2024 saw the 19^th edition of the Salon Privé. From tentative beginnings, this has grown to be one of the most significant events in the UK motoring calendar. For the past few years it has been held in the dignified setting of Blenheim Palace. The majority of the event takes place during the working week, and ticket prices are eye watering, though it seems that a surprisingly large number of people manage to blag free entry as journalists, photographers or “influencers”, as well as many who are invited by the high end dealers who attend. A lot changes in time for the weekend. This time there was only one day for what has now become the largest premium supercar party the UK has ever seen, called Supercar Saturday. Salon Privé. In 2024 the biggest single day of the five-day event saw 1,540 privately owned sports, super and hypercars descend on the North Lawn of Blenheim, all hoping to walk away with one of the prized Salon Privé Club Trophies presented by Lockton. This year’s line-up of car clubs, 26 in total, included the Aston Martin Owners Club, Ferrari Owners’ Club, Jaguar Enthusiasts Club, Lamborghini Club UK, Lotus Drivers Club, Maserati Club UK, McLaren Owners Club UK, Mercedes-Benz Club, Morgan Sports Car Club, Porsche Club Great Britain, and the Rolls-Royce & Bentley Enthusiasts’ Club, to name a few. Needless to say, it took quite a while to get all that lot in and parked up, and indeed, I queued up for over an hour to enter. Once parked up, here is what I saw.

There two parts to the report, the first concentrates on the Supercar displays. whilst the second covers the core of the Salon Privé event.

SUPERCAR DISPLAYS

ABARTH

I had arranged a display area for Abarths, following a most pressing invitation from the organiser who was keen that we attend. Sadly, the response from the community was not that great, but there were a few people who signed up. When I finally got through all the queues of display cars to the area I thought we were parking in, there was no signage to indicate our precise spot. I asked a marshall who was not much help, and after going up and down the long straight a couple of times, ended up at a point where had there been a sign I would have seen that we were supposed to double back on ourselves, but not spotting this, I got swept into the stream of cars going to general parking, and no amount of protesting made it possible to do anything other than park in the general car park. I was not the only Abarth to experience this.

Some Abarths did end up in the area designated for us. Notable here were 595s, in Series 4 guise. What is known as the Series 4 version of the familiar 595 reached the markets in the middle of 2016. After rumours had circulated all winter following the launch of the facelifted Fiat 500 last year, Abarth finally unveiled the Series 4 at the end of May 2016. Initially, we were told that the cars would not be available in the UK until September, but that came forward somewhat, with dealers all receiving demo cars in June, and the first customers taking delivery in July. Three regular production versions of both the closed car and the open-topped C were initially available, all badged 595, and called Custom, Turismo and Competizione, as before, though numerous limited edition models have since appeared and in most case disappeared. The most significant changes with the Series 4 are visual, with a couple of new colours, including the much asked for Modena Yellow and a different red, called Abarth Red, which replaces both the non-metallic Officina and – slightly surprisingly – the tri-coat pearlescent Cordolo Red. as well as styling changes front and rear. The jury is still out on these, with many, me included, remaining to be convinced. At the front, the new air intake does apparently allow around 15 – 20 % more air in and out, which will be welcome, as these cars do generate quite a lot of heat under the bonnet. Competizione models for the UK retain the old style headlights, as they have Xenon lights as standard, whereas the Custom and Turismo cars have reshaped units. At the back, there are new light clusters and a new rear bumper and diffuser. Inside, the most notable change is the replacement of the Blue & Me system with a more modern uConnect Audio set up, which brings a new colour screen to the dash. Mechanically, there is an additional 5 bhp on the Custom (now 145) and Turismo (now 165 bhp) and the option of a Limited Slip Diff for the Competizione, which is likely to prove a popular option. Details of the interior trim have changed, with a filled-in glovebox like the US market cars have always had, and electric windows switches that are like the US ones, as well as a part Alcantara trim to the steering wheel in Competizione cars.

The Abarth 124 Spider was developed in parallel with the Fiat model. It does cost a lot more, and there are those who think you don’t get enough extra for your money, but those who have driven it will tell you otherwise. You certainly get more power. The 1.4 MultiAir turbo unit jumps up from 138bhp to 168bhp, while torque also increases by a modest 10Nm to 250Nm, which gives it a  0-62mph time of  6.8 seconds, which is half a second quicker than the 2.0-litre Mazda MX-5. The top speed is 143mph. It weighs just 1060kg meaning a power-to-weight ratio of 158bhp-per-tonne, and with the new Record Monza exhaust system it sounds great even at idle. The Abarth version gets a stiffer suspension setup than the regular Fiat 124 Spider, with Bilstein dampers and beefed-up anti-roll bars. Bigger Brembo brakes also feature, with aluminium calipers. It can be had with a six-speed manual or six-speed automatic transmission with paddles, and the latter gets a Sport mode for quicker shifts. Many of the UK cars sport the ‘Heritage Look’ pack, which is a no-cost option. It brings a matt black bonnet and bootlid, plus red exterior trim detailing and has proved popular. The £29,565 starting price gets you standard equipment such as cruise control, climate control, Bluetooth, a DAB radio and satnav, plus Alcantara black and red (or pure black) seat trim. The automatic gearbox is a £2,035 extra, while an optional visibility pack brings LED DRLs, auto lights and wipers and rear parking sensors. Sales ceased during 2019, with around 1800 cars having been brought into the UK, so this is always going to be a rare car, and values are already increasing at a rate reflecting its desirability and the difficulty in finding one.

Parked elsewhere in the event was this super rare 695 Biposto Officine. Just 99 were made, in 2015/6 and initially they were sold to Ferrari dealers to use as courtesy cars much as the earlier Ferrari Dealer Edition car had been and this time there was a clause prohibiting sale for at least 6 months.  No-one is quite sure how many of these are in the UK, but we think probably fewer than 10. They are all numbered and Nick’s car is number 009. Ben Au owns car number 010. but that is currently in Hong Kong. It is known 10 Rosso Officine examples were available in Japan, possibly 30 examples went to Italy, possibly 10 examples to Germany and possibly 8 examples to Switzerland. Just 2 examples were sold and delivered to Australia. Car #1 was an Italian car, now living in Manila, Philippines. And #99 is a UK car. When they were deemed ready for sale, Rosso Officine models sold for around £45,000 in the UK, marking them out as the pinnacle of Bipostos. These cars were all painted in the same shade of Rosso Officina and were mechanically the same as the slightly more numerous Biposto and the Biposto Record. Abarth focused on the two key goals of weight reduction and engine performance. Out went the rear seats, air-conditioning, audio system, door cards, posh headlamps, fog lights et al. In came a Poggipolini tubular titanium roll-cage, cargo nets, 695 Biposto-specific Sabelt seats, Brembo brakes, 18in OZ alloys with bespoke 215/35 Goodyears, Extreme Shox adjustable shock absorbers, an Akrapovic exhaust system, a wider track and a 1.4-litre turbo powerplant lifted pretty much piecemeal from a Formula 4 single-seater. The Garrett turbocharged 1368cc unit spits out a feisty 187bhp at 5500rpm (the company claiming a 139hp-per-litre ‘record for this category’) and 184lb ft of torque at 3000rpm, dropping 0-62mph acceleration one tenth below the targeted 6.0 second mark and offering a top speed of 143 mph.

ALFA ROMEO

The 2600, or 106 Series, were an evolution of the model first seen in 1958 as a replacement for the 1900, and called the 2000 and known internally as the 102 Series. This was the time when Alfa was still in transition from being a maker of exclusive coachbuilt and racing cars to one that offered volume production models. The 102 Series were never likely to be big sellers, in a world that was still recovering economically from the ravages of the Second World War, but the range was an important flagship, nonetheless. The 2000 models ran for 4 years, from 1958 to 1962, at which point they were updated, taking on the name of 106 Series, with minor styling changes being accompanied by a larger 2600cc engine under the bonnet. As with the 2000 models, the new 2600 cars were sold in Berlina (Saloon), Sprint (Coupe) and Spider (Convertible) versions, along with a dramatically styled SZ Coupe from Italian styling house Zagato and a rebodied Berlina from OSI, all of them with an inline twin overhead cam six cylinder engine of 2.6 litres, the last Alfas to offer this configuration. Just 6999 of the Sprint models were made and 2255 Spiders, very few of which were sold new in the UK where they were exceedingly expensive thanks to the dreaded Import Duty which made them much more costly than an E Type. Many of the parts were unique to these cars, so owning one now is far harder than the more plentiful 4 cylinder Alfas of the era. Whilst the rather square styling of the Berlina, which won it relatively few friends when new and not a lot more in recent times means that there are few of these versions to be seen, the Sprint and Spider models do appear from time to time, and market interest in the cars is now starting to accelerate, with values rise accordingly. Seen here were the regular Coupe, the Spider and the 2600 Zagato.

Alfa replaced the Giulia-based Spider model with an all-new design which finally made its debut in 1966 together with the Giulia Sprint GT Veloce at an event organised in Gardone Riviera. With its boat tailed styling, it quickly found favour, even before taking a starring role in the film “The Graduate”. The original 1600cc engine was replaced by a more powerful 1750cc unit at the same time as the change was made to the rest of the range, and the car continued like this until 1970, when the first significant change to the exterior styling was introduced on the 1750 Spider Veloce, with the original’s distinctive elongated round tail changed to a more conventional cut-off tail, called the “Kamm tail”, as well as improving the luggage space. Numerous other small changes took place both inside and out, such as a slightly different grille, new doorhandles, a more raked windscreen, top-hinged pedals and improved interior trim. 1971 saw the Spider Veloce get a new, larger powerplant—a 1962 cc, 132 hp unit—and consequently the name was changed from 1750 Spider Veloce to 2000 Spider Veloce. The 1600 Spider restarted production a year later as the Spider 1600 Junior, and was visually identical to the 1300. 1974 saw the introduction of the rare, factory request, Spider-Targa. Based upon the Spider, it featured a Porsche style solid rear window and lift out roof panels, all made out of black GRP type material. Less than 2,000 models of such type were ever made and was the only part solid roof Spider until the introduction of the factory crafted hard top. The 1300 and 2000 cars were modified in 1974 and 1975 respectively to include two small seats behind the front seats, becoming a “two plus two” four seater. The 1300 model was discontinued in 1977. Also, between 1974 and 1976, the early-style stainless-steel bumpers were discontinued and replaced with black, rubber-clad units to meet increasingly stringent North American crash requirements. 4,557 examples of the 1300 Junior were made and 4,848 of the 1600 Junior as well as 16,320 2000 Spider Veloces and 22,059 of 2000 Spider Veloce US version. There were also 4,027 1750 Spider Veloces produced.

When the 156 was launched in 1997, things looked very bright for Alfa. Striking good looks were matched by a driving experience that the press reckoned was better than any of its rivals. The car picked up the Car of the Year award at the end of the year. and when it went on sale in the UK in early 1998, waiting lists soon stretched out more than 12 months. Reflecting the way the market was going, Alfa put a diesel engine under the bonnet, launched a (not very good, it has to be admitted) automated transmission with the SeleSpeed, added a very pretty if not that commodious an estate model they called Sport Wagon and then added a top spec 3.2 litre GTA with its 250 bhp engine giving it a performance to outrun all its rivals. And yet, it did not take long before the press turned on the car, seduced by the latest 3 Series once more, citing build quality issues which were in fact far from universal. The 156 received a very minor facelift in 2002 and a more significant one in late 2003 with a new front end that was a clue to what would come with the car’s successor. Production ceased in 2005.

Although I am sure there are those who would beg to differ, my contention is that car styling in the twentyfirst century has gone through a period which will not be viewed particularly positively in years to come, with a myriad of forgettable designs and more recently plenty which in trying to be distinctive are just downright ugly. There have been a few high points, though, and top of that list for me must be the Alfa 8C Competizione, a lone example of which was to be seen here. As well as the looks, this car also has noise on its side, with a sound track which must rate as one of the best of recent times. So that is two boxes ticket for me. The press saw it rather differently, and were rather critical of the car when it was new, but for me, finding plenty to fault with the way the car drove. First seen as a concept car at the Frankfurt Motor Show in 2003, the concept was conceived as a reminder for  people who were perhaps slightly disillusioned with contemporary Alfa products that the company could still style something as striking in the 21st century as it had been able to do in the 1950s and 1960s. Public reaction was very positive, but Fiat Group Execs were very focused on Ferrari and Maserati and they were not entirely convinced that a car like this was appropriate as it could encroach on those brands’ territory. It was only in 2006, with new management in place that it is decided that a limited production run of just 500 cars would give the once proud marque something of a boost. Announcement of the production version, visually little different from the 2003 concept car was made at the 2006 Paris Show, and it was soon evident that Alfa could have sold far more than 500 cars To turn the concept into reality, Alfa used a shortened Maserati Quattroporte platform with a central steel section, subframes front and rear and main outer panels that were all made from carbon fibre, with the result that the complete car weighed 300 kg less than the GranTurismo. Final assembly was carried out by Maserati, with the cars being built between 2007 and 2010. Competiziones (Coupes) first, and then 500 Spiders. Just 40 of the Competizione models came to the UK. Most of them were sent to the US, so this car is exceptionally rare and is much sought after by collectors. They were fearsomely expensive when new, listing for around £150,000, but prices have never dipped far below this, so anyone who bought one, should they ever feel the need to sell it, is not going to lose money on the car.

Rather than replacing the 916 Series GTV with a single model, Alfa elected to produce two successors., The more commodious of the two, the GT, was the first to appear, making its debut in March 2003 at the Geneva Motor Show, finally going on sale in early 2004. It was built at the Pomigliano plant, alongside the 147 and 159. The GT was based on the Alfa 156 platform, which was also used for the 147, providing the 2-door coupé with genuine five-passenger capacity. It was styled by Bertone. Most mechanicals were taken directly from the 156/147 using the same double wishbone front suspension and MacPherson rear setup. The interior was derived form the smaller hatchback 147 and shared many common parts. The GT shared the same dash layout and functions, the climate control system as well as having a similar electrical system. Some exterior parts were taken from 147 with the same bonnet, wing mirrors and front wings (from 147 GTA). The engine range included both a 1.8 TS, and 2.0 JTS petrol engine, a 1.9 MultiJet turbodiesel, and a top-of-the-range 240 bhp 3.2 V6 petrol. There were few changes during the GT’s production life. In 2006 Alfa introduced a 1.9 JTD Q2 version with a limited slip differential, and also added a new trim level called Black Line. In 2008 Alfa introduced the cloverleaf model as a limited edition complete with new trim levels, lowered suspension, body kit, 18 inch alloy wheels and was only available in the colours black, Alfa red, or blue. with 1.8 and 2.0 litre petrol engines as well as the 1.9 litre Multijet turbo diesel. The GT was acclaimed for its attractive styling and purposeful good looks, in 2004 being voted the world’s most beautiful coupe in the annual ‘World’s Most Beautiful Automobile’ (L’Automobile più Bella del Mondo) awards. The car sold reasonably well, with 80,832 units being produced before the model was deleted in 2010.

Visually similar to the 159 models at the front, the Brera and Spider boasted unique styling from the A pillars rearwards. They were offered with the same range of engines as the 159, and thanks to that strong, but rather heavy platform on which they were built, even the 3.2 litre V6 cars were more Grand Tourer than rapid sports car. Pininfarina was responsible for both models. The Brera was first to market, in 2005, with the Spider following in 2006. Production of both ceased in late 2010, by which time 12,488 units of the Spider and 21,786 units of the Brera had been built. It will be very surprising if these do not attain classic status, and the consequent rise in values, though that has not happened yet.

The Alfa Romeo 4C is a two-seater, rear-wheel drive coupé with technology and materials derived from the Alfa Romeo 8C Competizione, with a 1750 cc turbo petrol engine with direct injection, the “Alfa TCT” twin dry clutch transmission, and the Alfa DNA dynamic control selector. The 4C concept version was unveiled in the 81st Geneva Motor Show in March 2011, followed by the Mille Miglia 2011 parade, Goodwood Festival of Speed 2011,2011 Frankfurt Motor Show. It was displayed for the first time outside in Concorso d’Eleganza Villa d’Este in 2012. Compared to the production version, it is very similar, with the biggest differences being front lights, side vents and mirrors. The Alfa Romeo 4C Concept was voted the ‘Most Beautiful Concept Car of the Year’ award by the readers of German magazine Auto Bild, and won the Auto Bild Design Award 2011. It was awarded the “Design Award for Concept Cars & Prototypes” by referendum of the public in Villa d’Este. The production car was unveiled at the 2013 Geneva Motor Show, followed by 2013 Essen ‘Techno Classica’, Goodwood Festival of Speed 2013, Moscow Raceway, 2013 Frankfurt Motor Show. The bare ‘4C000’ chassis was also shown at the 2013 Geneva Motor Show. Ordering of European models began in October 2013 at Alfa Romeo dealerships in Europe. As part of the Alfa Romeo 4C launch, Alfa Romeo Style Centre and Compagnia Ducale designed a 4C IFD (Innovative Frame Design) Bicycle, inspired by the Alfa Romeo 4C coupé. The vehicle went on sale in December 2013 and marketed in Europe, Asia and America. Production of the 4C began May 2013 at Maserati’s plant in Modena, with an expected production of up to 2500 units per year. It was the first mass-produced Alfa Romeo model to be sold in the US market since 1995 when the 164 sedan stopped being sold in the US. Production of the Alfa Romeo 4C was originally estimated to be over 1000 units per year, with an upper limit of 3500 units per year, depending on the quantity of carbon fibre chassis that can be built by the supplier Adler Plastic.Within the 3,500-unit quota, 1,000 units are earmarked for Europe. Delivery of the European Alfa Romeo 4C Launch Edition took place at Balocco (Vercelli, Italy) Test Centre. In 2018, the 4C coupe was discontinued for the North American market. The 4C Spider, however continued to be sold there for model year 2019 and model year 2020. In other markets, such as Australia and Japan, both the coupe and Spider continued. In late 2020, a new tribute-edition named the 4C Spider 33 Stradale Tributo was announced. The car was designed by Centro Stile Alfa Romeo (Style Centre) and developed by Alfa Romeo. The chassis is composed of a central carbon fibre tub, with aluminium subframes front and rear. The carbon fibre tub is produced by TTA (Tecno Tessile Adler) in Airola, as a joint venture between Adler Plastic and Lavorazione Materiali Compositi. The carbon fibre components that make up the chassis are cut using CNC technology. The entire carbon-fiber monocoque chassis (“tub”) of the car weighs 143 pounds (65 kg). Front and rear aluminium subframes combine with the tub, roof reinforcements and engine mounting to comprise the 4C chassis giving the vehicle a total chassis weight of 236 lb (107 kg) and a total vehicle curb weight of just 2,465 lb (1,118 kg). The 4C has a single carbon fibre body, similar to the body of many supercars. The outer body is made of a composite material (SMC for Sheet Moulding Compound) which is 20% lighter than steel. The stability is comparable to steel and better than aluminium. The 4C employs double wishbone suspensions at the front and MacPherson struts at the rear. The resultant weight distribution is 38% on the front and 62% on the rear axle. Wheels and tyres have different diameters and widths front and rear: 205/45 R17 front and 235/40 R18 back as standard, with optional 205/40 R18 and 235/35 R19. Both wheel options come equipped with Pirelli P Zero tyres. The 4C uses vented disc brakes on all wheels; Brembo 305 millimetres (12.0 in) on the front and 292 millimetres (11.5 in) on the rear. The car can stop from 100 km/h (62 mph) in 36 metres. To save weight and increase steering feel, the 4C has no power steering. Its center of gravity height, at 40 centimetres (16 in) off the ground, is 7 centimetres (2.8 in) lower than that of the Lotus Elise. The 4C uses a new all-aluminium 1,742 cc inline 4 cylinder turbocharged engine producing 240 PS at 6000 rpm. The engine has been designed for minimum weight. The engine’s combined fuel consumption 6.8 l/100 km (42 mpg‑imp; 35 mpg‑US).[4] 0–62 mph (0–100 km/h) acceleration is achieved in 4.5 seconds and the top speed is 258 km/h (160 mph), the power-to-weight-ratio being just 0.267 hp/kg (8.22 lb/hp) A journalist from Quattroruote car magazine demonstrated how the 4C accelerates from 0–100 km/h (0–62 mph) faster than 4.5 seconds. In race mode, with left foot on the brake pedal, if you pull the right shift paddle the engine will rev to 3500 rpm, but if you also pull the left paddle the engine will rev to 6000 rpm and 0–100 km/h (0–62 mph) time will go down to 4.2 seconds. Italian car magazine Quattroruote published the lap time of 4C around Nürburgring. It lapped the ring in 8:04. The 4C is equipped with a six speed Alfa TCT Dual Dry Clutch Transmission, and can be operated via gearshift paddles on the steering wheel. It also has an Alfa ‘DNA’ dynamic control selector which controls the behavior of engine, brakes, throttle response, suspension and gearbox. In addition to the modes already seen in Giulietta, the 4C has a new “Race” mode. The U.S. version of the 4C was introduced in the 2014 New York International Auto Show with the first 100 4C’s being shipped to the U.S. early July, with a total of 850 being shipped by the end of 2014. The U.S. model includes extra bracing and strengthening required to meet U.S. crash regulations (including aluminium inserts in the carbon fiber chassis), resulting in 100 kg (220 lb) of weight increase. This version also has new headlamps similar to those seen before in the 4C Spider version. In 2018, the 4C coupe was discontinued for the North American market due to US DOT NHTSA FMVSS 226 Ejection Mitigation. The regulation called for a progressive compliance date based on volume and, due to low volume, the 4C was allowed to continue until the last compliance date of 9/1/2017, thus all 2018 4C coupes in North America have build dates of 8/2017 or earlier. The 4C Spider, however continued to be sold in North America for model year 2019 and model year 2020. The Spider version of the 4C was previewed showing a pre-production prototype at the 2014 Geneva Motor Show. Sharing its engine with the Coupé version, the 4C Spider has different external parts such as the headlights, exhaust and engine hood, as well as a different roof section that features a removable roof panel. The North American spec 4C reflects a weight difference of only 22 lb (10 kg) (2,465 lbs vs. 2,487 lbs) for the Spider variant. Top speed is quoted at 257 km/h (160 mph) and acceleration from 0 to 100 km/h (62 mph) at 4.5 seconds. The 4C Launch Edition was a limited and numbered edition, unveiled at the vehicle’s launch at the 2013 Geneva Motor Show. The vehicle came in a choice of four paint colours (Rosso Alfa, Rosso Competizione tri-coat, Madreperla White tri-coat or Carrara White matte). 500 examples were reserved for Europe/ROW, 500 for North America, 88 for Australia (Rosso Alfa and Madreperla White only), 200 to Japan and 100 for the Middle East. Note that the original press release cited 500 for North America, 400 Europe, and 100 ROW; however, the plaques on actual cars suggest that more were built and are the numbers referenced above. Distinguishing features of the Launch Edition were carbon fiber trim (including headlight housings, spoiler and door mirror caps), rear aluminium extractor with dark finishing, Bi-LED headlights, dark painted 18-inch front and 19-inch rear alloy wheels, additional air intakes on the front fascia, red brake calipers, racing exhaust system, BMC air cleaner, specific calibration for shock absorbers and rear anti-roll bar, leather/fabric sports seats with parts in Alcantara and a numbered plaque. Alfa Red coloured cars got matching red stitching on the steering wheel, handbrake, mats, handles and sports seats. In Europe the vehicle went on sale for 60,000 euros including VAT. The 4C Competizione is a limited edition version of the 4C introduced in the 2018 Geneva Motor Show, finished in matte Vesuvio Grey, with carbon details on the roof, rear spoiler, mirror caps, side air vents and headlight moulding. The run reportedly consisted of 108 units. The Japanese market received 25 units, and 10 units were assigned to Australia. The US-market received no Competizione editions. The car had a very mixed reaction. The UK press hated it at launch, but owners generally disagreed and loved it. A total of 9117 were built before production ceased in 2020.

Final Alfa in the relatively small display organised by Alfa Romeo Owners Club was the modern and still current Giulia.

ALVIS

The Alvis Three Litre, also known as TC 21 is an automobile produced by British manufacturer Alvis between 1953 and 1955. An updated version of the Three Litre TA 21, it was available as a 4-door saloon and, in its later TC 21/100 form, also as a 2-door drophead coupé. The TC 21 was available as four-door saloon but, unlike its TA 21 predecessor, no drophead version was offered. The bodies were made for Alvis by Mulliners (Birmingham). A sunshine roof remained standard as did “separately adjustable front seats; heater and air-conditioning unit; Trico windscreen washers” drawing the comment from Autocar “In detail fittings . . . this car leaves little to be desired”. The 2,993 cc engine was upgraded to produce 100 bhp by modifying the cylinder head and fitting twin SU carburettors. Suspension was the same as the TA 21, independent at the front using coil springs with leaf springs at the rear. The 11 in (279 mm) drum brakes using a Lockheed system were also retained. However this update found few buyers during a very difficult year for the British Motor Industry and though it remained in the catalogue and continued to be advertised it was in practice replaced by the Grey Lady. The TC.21/100 or Grey Lady announced 20 October 1953 came with a guarantee of a speed of 100 mph resulting from an improved exhaust system and an engine compression ratio raised from 7:1 to 8:1 to take advantage of the availability of better petrol. The final drive ratio was raised from 4.09:1 to 3.77:1. A paired front fog lamp and matching driving lamp became a standard fitting. The bonnet gained air scoops and wire wheels were fitted to try to enliven the car’s image. A heater was fitted as standard but a radio remained an expensive option. Four door saloon and drophead coupé versions were offered. A saloon version tested by The Motor magazine in 1954 had a top speed of 100.1 mph (161.1 km/h) and could accelerate from 0-60 mph (97 km/h) in 15.4 seconds. A fuel consumption of 20.6 miles per imperial gallon (13.7 L/100 km; 17.2 mpg‑US) was recorded. The test car cost £1,821 including taxes. Nevertheless, just 18 months later the Times’ Motoring Correspondent tested and reported on the Grey Lady under the headline “Few Concessions to Fashion Trends”. His opening gambit was that this Alvis was now one of the few British cars that did not look American and, he said, there was little concession to the cult of streamlining beyond the two air scoops in the bonnet. He wrote that spacious internal headroom and wire wheels completed that picture. It was noted the instruments were not in front of the driver but in the centre of the dashboard (instrument panel) and so the speedometer was apt to be masked by the driver’s left hand. However the front seats were comfortable and rear seat passengers received padding on the wheel arches surmounted by armrests. Leather upholstery, pile carpets and walnut facings for the dashboard and lower parts of the window frames completed the traditional picture. He did however say that “the driver who is sensitive to the “feel” of his car will enjoy every moment of his motoring irrespective of the traffic” and reported the car’s behaviour on corners was extremely stable though potholes like those caused by recessed manhole covers proved very heavy going for the springing. A Graber-bodied coupe on a TC 21/100 chassis was exhibited at the London Motor Show in October 1955.[9] The similar TC 108G entered limited production the following year.

ASTON MARTIN

The DB2/4 was the first new post-war Aston, and the first car to adopt the now legendary DB naming convention, reflecting the fact that in 1947 David Brown had bought the Aston Martin and Lagonda companies and incorporated them as Aston Martin Lagonda Ltd. Lagonda’s 2.6 litre dual overhead cam, straight-six engine, more powerful than the pushrod 1.9 litre unit in the Aston Martin 2-Litre Sports, was the main objective in Brown’s acquisition of the company. W. O. Bentley had supervised the engine’s design, which was largely by William (Willie) Watson, an engineer with the pre-war Invicta company who had collaborated on Lagonda’s pre-war V12 and also designed the short-lived post-war version. Work then started on producing a new car, which was called the DB2. This new model would utilise a version of the Lagonda engine in a shortened version of the tube-frame chassis designed by Claude Hill for the Aston Martin 2-Litre Sports, with a fastback coupé body designed by Frank Feeley. Three pre-production cars were entered for the 1949 24 Hours of Le Mans. One, which would become the development car for the production DB2, had the Lagonda straight-6, while the four-cylinder Aston Martin 2-litre unit powered the other two. After six laps the Lagonda-powered car, driven by Leslie Johnson, retired with overheating caused by failure of the water pump. One of the 2-litre cars was in 4th place and running without brakes when it crashed two hours short of the finish, fatally injuring driver Pierre Maréchal. The other finished 7th, crewed by Arthur Jones and Nick Haines. A month later, the larger-engined car, driven by Leslie Johnson and Charles Brackenbury, finished 3rd in the Spa 24-hour race, where one of the 2-litre cars was driven to 5th by Nick Haines and Lance Macklin. For 1950 all three factory team cars were equipped with the Lagonda engine. At the 1950 Le Mans race the one driven by George Abecassis and Lance Macklin finished 5th, with Brackenbury and Reg Parnell bringing another home 6th, which won Aston Martin 1st and 2nd in the 3-litre class. Across the Atlantic, Briggs Cunningham drove his DB2 to 2nd in its class at the inaugural Sebring race meeting in December 1950. The factory team cars continued racing in Europe throughout 1951, including at Le Mans, where Macklin and Eric Thompson took 3rd overall, with Abecassis and Brian Shawe-Taylor 5th. David Brown soon embarked on a series of Aston Martins designed specifically for competition use, starting with the DB3. Meanwhile, the production DB2 debuted at the New York Auto Show in April 1950 and continued in production until April 1953, by which time 411 had been made. The first 49 had a chrome-framed front grille in three separate parts, and large rectangular cooling vents in the front wings. Subsequent cars had a one-piece grille with horizontal chrome slats, and no side vents. The single-piece bonnet was hinged at the front. At the rear of the fixed-head coupé (FHC) a small top-hinged lid gave access to the spare wheel, and luggage space was behind the front seats, accessible only from inside the car. Later in 1950, a Drophead Coupé (DHC) variant was introduced. At least 102 were built. In April 1950, an engine with larger carburettors, inlet camshaft the same as the exhaust (for increased duration), and higher compression ratio pistons (8.16:1) was made available. Aston Martin’s first Vantage upgrade option offered 125 hp. Initially the higher compression ratio made the engine unsuitable for the British market, as the postwar austerity measures of the early 1950s restricted UK vehicles to 72 octane “Pool petrol”. The first DB2 Vantage, LML 50/21, was delivered to, and raced by, Briggs Cunningham in the United States. A revised version of the DB2 was launched in 1953, called the DB2/4. It was available as a 2+2 hatchback, marketed as a Saloon, as a Drophead Coupé (DHC) and as a 2-seat Fixed Head Coupe. A small number of Bertone bodied spiders were commissioned by private buyers. A further update in 1957 created the Mark III, and this was produced until the launch of the DB4 in 1958.

There were a number of DB6 cars, a model which was launched in 1965 as a replacement for the DB5 which had run since 1963. The wheelbase was now 4″ longer than before, resulting in an extensive restyle with a more raked windscreen, raised roofline and reshaped rear quarter windows. Opening front quarter lights made a reappearance, but the major change was at the rear where a Kamm tail with spoiler improved the aerodynamics, greatly enhancing stability at high speeds. “The tail lip halves the aerodynamic lift around maximum speed and brings in its train greater headroom and more luggage space”, declared Motor magazine, concluding that the DB6 was one of the finest sports cars it had tested. Famed employee, Tadek Marek, designed the six cylinder engine, which had been enlarged to 3,995cc for the preceding DB5 and remained unchanged. Power output on triple SU carburettors was 282bhp, rising to 325bhp in Vantage specification. Premiered at the 1965 London Motor Show, the DB6 Volante marked the first occasion the evocative ‘Volante’ name had been applied to a soft-top Aston Martin. After 37 Volante convertibles had been completed on the DB5 short wheelbase chassis, the model adopted the longer DB6 chassis in October 1966. A mere 140 DB6 based Volantes were manufactured, and of these only 29 were specified with the more powerful Vantage engine.

Representing the longest lived design in Aston Martin’s history were a number of DBS and V8 cars. By the mid 1960s, Aston Martin’s customers had been clamouring for an eight-cylinder car, so Aston Martin designed a larger car. The engine was not ready, however, so in 1967 the company released the DBS with the straight-six Vantage engine from the DB6. Two years later, Tadek Marek’s V8 was ready, and Aston released the DBS V8. Though the body and name was shared with the six-cylinder DBS, the V8 sold for much more. The body was a modern reinterpretation of the traditional Aston Martin look, with a squared-off grille and four headlights (though some consider the styling derivative of the early Ford Mustang). Distinguishing features of the V8 model are the larger front air dam and lack of wire wheels, though some six-cylinder DBS cars also used the V8’s alloy wheels. The tail lights were taken from the Hillman Hunter. A road test report of the time noted that the car had gained 250 lb in weight with the fitting of the V8 in place of the previously used six-cylinder unit, despite the manufacturer’s assurance that the engine weighed only 30 lb more than the older straight-six. Other contributions to the weight gain included heavier ventilated brake discs, air conditioning, fatter tyres, a new and stronger ZF gearbox as well as some extra bodywork beneath the front bumper. Marek’s V8 engine displaced 5,340 cc and used Bosch fuel injection. Output was not officially released, but estimates centre around 315 hp. The DBS V8 could hit 60 mph in 5.9 seconds and had a top speed of nearly 160 mph. 402 DBS V8s were built. In April 1972, the DBS V8 became just the Aston Martin V8 as the six-cylinder DBS was dropped, leaving just this car and the six-cylinder Vantage in production. The V8 became known as the AM V8, a model retroactively referred to as the Series 2 V8 to separate it from later models. Visual differences included twin quartz headlights and a mesh grille, a front design which was to last until the end of production in 1989. AM V8 cars, produced from May 1972 through July 1973, used a similar engine to the DBS V8, albeit with Bosch fuel injection rather than the earlier carburettors. Just 288 Series 2 cars were built. Although David Brown had left the company, he had overseen development of this model. The first 34 cars still carried leftover “DBS V8” badging. The car switched back to Weber carburettors for the Series 3 in 1973, ostensibly to help the car pass new stricter emissions standards in California but most likely because Aston Martin was unable to make the Bosch fuel injection system work correctly. These cars are distinguished by a taller bonnet scoop to accommodate four twin-choke (two-barrel) Weber carbs. The car produced 310 hp and could reach 60 mph in 6.1 seconds with an automatic transmission or 5.7 with a manual. Performance suffered with emissions regulations, falling to 288 hp in 1976. The next year, a more powerful “Stage 1” engine with new camshafts and exhaust brought it up to 305 hp. Production of Series 3 cars lasted from 1973 through October 1978, but was halted for all of 1975. 967 examples were produced in this time. While earlier V8 cars have louvers cut into the little panel mounted beneath the rear windshield, the Series 3 and later cars instead have a small lip at the bottom of this panel, just ahead of the leading edge of the bootlid. The “Oscar India” specification was introduced in October 1978 at the Birmingham International Motor Show. Visually, the former scoop on the bonnet gave way to a closed “power bulge”, while a spoiler was integrated into the tail. Most Oscar India cars were equipped with a Chrysler “Torqueflite” three-speed automatic transmission, with wood trim fitted for the first time since the DB2/4 of the 1950s. Just 352 Oscar India models were built from 1978 through 1985. The power of the now de-smogged engines kept dropping on American market cars, down to a low of 245 hp in the early eighties. The convertible “Volante” was introduced in June 1978, but featured the Series 4 bonnet a few months before the coupé received the Oscar India update. The Volante Series 1 weighs 70 kg (155 lb) more than the coupé, due to the necessity of reinforcing the frame. US market cars received much larger bumpers beginning with the 1980 model year, adding weight and somewhat marring the car’s lines. Owners of US-specified cars often modify them to have the slimmer European bumpers. By 1981, the success of the Volante meant that the coupé model was only built on individual demand. The fuel-injected Series 5 cars were introduced in January 1986 at the New York International Auto Show. The compact Weber/Marelli system no longer needed the space of the previous carburettors, so the bonnet bulge was virtually eliminated. 405 Series 5 cars were built before production ceased in 1989. The Volante Series 2 received the same changes; 216 were built.

After a production run of over 20 years, Aston came up with a new body shape for the 1988 Birmingham Motor Show, and called the new car the Virage. Initially announced solely as a close coupe, it was not long before an open-topped model was added to the range and then in 1993, these were joined by the high-performance Vantage. The name of the base model was changed to V8 Coupé in 1996. The V8-powered model was intended as the company’s flagship model, with the 6-cylinder DB7, introduced in 1994, positioned below it as an entry-level model. Although the DB7 became available with a V12 engine and claimed a performance advantage, the Virage remained the exclusive, expensive and hand-built flagship of the Aston Martin range. It was replaced in 2000 with the Vanquish. By the end of the 2000 model year, 1,050 cars in total had been produced

With the DB7, produced from September 1994 to December 2004, Aston Martin made more cars from a single model than all Astons previously made, with over 7000 built. Known internally as the NPX project, the DB7 was made mostly with resources from Jaguar and had the financial backing of the Ford Motor Company, owner of Aston Martin from 1988 to 2007. The DB7’s platform was an evolution of the Jaguar XJS’s, though with many changes. The styling started life as the still-born Jaguar F type (XJ41 – coupe / XJ42 – convertible) designed by Keith Helfet. Ford cancelled this car and the general design was grafted onto an XJS platform. The styling received modest changes by Ian Callum so that it looked like an Aston Martin. The first generation Jaguar XK-8 also uses an evolution of the XJ-S/DB7 platform and the cars share a family resemblance, though the Aston Martin was significantly more expensive and rare. The prototype was complete by November 1992, and debuted at the Geneva Motor Show in March, 1993, with the car positioned as an “entry-level” model below the hand-built V8 Virage introduced a few years earlier. With production of the Virage (soon rechristened “V8” following Vantage styling revisions) continuing at Newport Pagnell, a new factory was acquired at Bloxham, Oxfordshire that had previously been used to produce the Jaguar XJ220, where every DB7 would be built throughout its production run. The DB7 and its relatives were the only Aston Martins produced in Bloxham and the only ones with a steel unit construction inherited from Jaguar . Aston Martin had traditionally used aluminium for the bodies of their cars, and models introduced after the DB7 use aluminium for the chassis as well as for many major body parts. The convertible Volante version was unveiled at the North American International Auto Show in Detroit in 1996. Both versions have a supercharged straight-six engine that produced 335 bhp and 361 lb·ft of torque. The Works Service provided a special Driving Dynamics package, which greatly enhanced performance and handling for drivers who wanted more than what the standard configuration offered. In 1999, the more powerful DB7 V12 Vantage was introduced at the Geneva Motor Show. Its 5.9 litre, 48-valve, V12 engine produced 420 bhp and 400 lb·ft of torque. It has a compression ratio of 10.3:1. Transmissions were available with either a TREMEC T-56 six speed manual or a ZF 5HP30 five speed automatic gearbox. Aston Martin claimed it had a top speed of either 186 mph with the manual gearbox or 165 mph with the automatic gearbox, and would accelerate from 0–60 mph in 4.9 seconds. It is 4,692 mm long, 1,830 mm (72.0 in) wide, 1,243 mm (48.9 in) high, with a weight of 1,800 kg (3,968.3 lb). After the launch of the Vantage, sales of the supercharged straight-6 engine DB7 had reduced considerably and so production was ended by mid-1999. In 2002, a new variant was launched, named V12 GT or V12 GTA when equipped with an automatic transmission. It was essentially an improved version of the Vantage, its V12 engine producing 435 bhp and 410 lb·ft of torque for the manual GT, although the automatic GTA retained the 420 bhp and 400 lb·ft of torque of the standard DB7 Vantage. Additionally, the GT and GTA chassis had substantially updated suspension from the DB7 Vantage models. Aesthetically, compared to the Vantage it has a mesh front grille, vents in the bonnet, a boot spoiler, an aluminium gear lever, optional carbon fibre trim and new wheels. It also has 14.0 in front and 13.0 in rear vented disc brakes made by Brembo. When being tested by Jeremy Clarkson on Top Gear in 2003, he demonstrated the car’s ability to pull away in fourth gear and continue until it hit the rev limiter: the speedometer indicated 135 mph. Production of the GT and GTA was extremely limited, as only 190 GT’s and 112 GTA’s were produced worldwide with 17 of them shipped to the US market, for a total of 302 cars.

The Aston Martin V12 Vanquish was designed by Ian Callum and bore a large resemblance to the production DB7 Vantage. However, the car had a strong influence from the Project Vantage Concept prototype which debuted with a V12 engine at the North American International Auto Show in January 1998. As underneath the car featured a strong aluminium/carbon composite construction, bonded chassis with a 5,935 cc V12 engine. It was available in 2+0 and 2+2 seating configurations. The 48-valve 60° engine produces 460 bhp and 400 lb⋅ft of torque. It is controlled by a drive-by-wire throttle and a six-speed Electrohydraulic manual transmission. The standard Vanquish model had 14.0 inch drilled and ventilated disc brakes with four-pot calipers, ABS, with electronic brake distribution. Its appearance in the 2002 James Bond film Die Another Day earned the V12 Vanquish the number three spot on the list of Best Film Cars Ever, behind the Minis from The Italian Job, and DB5 from Goldfinger & Thunderball. The car also appears in the video games Need For Speed: Hot Pursuit 2, James Bond 007: Nightfire, and James Bond 007: Everything or Nothing. The Vanquish S debuted at the 2004 Paris Auto Show, with increased horsepower and performance and slight styling revisions. The engine displacement remained at 5,935 cc with power increased from 460 to 520 bhp. Visual changes included new wheels, a slightly different nose shape, a new raised bootlid with a larger integrated spoiler incorporating the third high level brake light (in the rear window on the original Vanquish), a Vanquish S badge on the bootlid (the original Vanquish had no rear model designation) and the addition of a small front splitter (although this was mainly done for aerodynamic reasons). As part of its improvements, the Vanquish S featured a slightly improved coefficient of drag of 0.32 (from 0.33), with help from a redesigned splitter and boot lid. Its front and rear track were 1,524 mm (60.0 inches) and 1,529 mm (60.2 inches), respectively. It also incorporated the features of a 2004 option package, the Sports Dynamic Pack, which incorporated sportier suspension, steering, and brake features. This model was sold for the 2005 (alongside the base Vanquish) and 2006 (as a stand-alone) model years in the United States with only minor running changes; it was not sold in the United States for 2007. The Vanquish S featured larger brakes than the V12 Vanquish; 14.9 in front discs with six-pot calipers and 13.0 inches rear discs. The end of the Vanquish’s production run was celebrated with the Vanquish S Ultimate Edition. Aston Martin announced that the last 50 cars built would have a new ‘Ultimate Black’ exterior colour, upgraded interior, and personalised sill plaques. 1086 Vanquish S were built. With a 200+ MPH top speed, the Vanquish S was (as measured by top speed capability) the fastest Aston Martin ever until the Vantage V12 S was introduced in May 2013. Vanquish production ended on 19 July 2007, coinciding with the closing of the company’s Newport Pagnell factory after 49 years of operation.

Follow on to the DB7 was the DB9 (there has never been a car called DB8 – supposedly because people might have assumed this meant a V8 engine), and there was a nice example here. Designed by Marek Reichmann and Hendrik Fisker, the DB9 was first shown at the 2003 Frankfurt Auto Show, in coupe form. It was widely praised for the beauty of its lines. This was the first model to be built at Aston Martin’s Gaydon facility. It was built on the VH platform, which would become the basis for all subsequent Aston models. The Aston Martin DB9 was initially launched equipped with a 6.0 litre V12 engine, originally taken from the V12 Vanquish. The engine produced 420 lbf·ft of torque at 5,000 rpm and a maximum power of 444 hp at 6,000 rpm, allowing the DB9 to accelerate from 0 to 60 mph in 4.7 seconds and a top speed of 299 km/h (186 mph). The engine largely sits behind the front-axle line to improve weight distribution. Changes to the engine for the 2013 model year increased the power to 503 hp and torque to 457 lb-ft, decreasing the 0 to 60 mph time to 4.50 seconds and with a new top speed is 295 km/h (183 mph). The DB9 was available with either a six-speed conventional manual gearbox from Graziano or a six-speed ZF automatic gearbox featuring paddle-operated semi-automatic mode. The gearbox is rear-mounted and is driven by a carbon-fibre tail shaft inside a cast aluminium torque tube. The DB9 was the first Aston Martin model to be designed and developed on Ford’s aluminium VH (vertical/horizontal) platform. The body structure is composed of aluminium and composites melded together by mechanically fixed self-piercing rivets and robotic assisted adhesive bonding techniques. The bonded aluminium structure is claimed to possess more than double the torsional rigidity of its predecessor’s, despite being 25 percent lighter. The DB9 also contains anti-roll bars and double wishbone suspension, supported by coil springs. To keep the back-end in control under heavy acceleration or braking, the rear suspension has additional anti-squat and anti-lift technology. Later versions of the car also features three modes for the tuning: normal, for every-day use, sport, for more precise movement at the cost of ride comfort, and track, which furthers the effects of the sport setting. The Aston Martin DB9 Volante, the convertible version of the DB9 coupe, followed a few months later. The chassis, though stiffer, uses the same base VH platform. To protect occupants from rollovers, the Volante has strengthened windscreen pillars and added two pop-up hoops behind the rear seats. The hoops cannot be disabled and will break the car’s rear window if deployed. In an effort to improve the Volante’s ride while cruising, Aston Martin have softened the springs and lightened the anti-roll bars in the Volante, leading to a gentler suspension. The retractable roof of the Volante is made of folding fabric and takes 17 seconds to be put up or down. The Volante weighs 59 kilograms (130 pounds) more than the coupe. The coupe and Volante both share the same semi-automatic and automatic gearboxes and engine. The car was limited to 266 km/h (165 mph) to retain the integrity of the roof. Like the coupe, the original Volante has 420 lb·ft of torque at 5,000 rpm and a maximum power of 450 hp at 6,000 rpm. The 0 to 60 mph slowed to 4.9 seconds due to the additional weight. The DB9 was facelifted in July 2008, which mainly amounted to an increase in engine power, to 476 hp and a redesigned centre console. Externally, the DB9 remained virtually unchanged. For the 2013 model year revision, Aston made minor changes to the bodywork by adapting designs from the Virage, including enlarging the recessed headlight clusters with bi-xenon lights and LED daytime strips, widening the front splitter, updating the grille and side heat extractors, updating the LED rear lights with clear lenses and integrating a new rear spoiler with the boot lid. .On newer models, like the coupe’s, the Volante’s horsepower and torque increased to 517 PS (510 hp) and 457 lb·ft respectively. As a finale for the model, a more powerful DB9 was released in 2015, called the DB9 GT. This had 540 bhp and 457 lb-ft of torque at 5500 rpm, giving a 0 to 60mph time of 4.4 seconds and 0 to 100mph in 10.2 seconds, with the standing quarter mile dispatched in 12.8 to 12.9 seconds and a top speed of 183mph.

 

Several of the recently superceded Vantage model were here. Following the unveiling of the AMV8 Vantage concept car in 2003 at the North American International Auto Show designed by Henrik Fisker, the production version, known as the V8 Vantage was introduced at the Geneva Motor Show in 2005. The two seat, two-door coupé had a bonded aluminium structure for strength and lightness. The 172.5 inch (4.38 m) long car featured a hatchback-style tailgate for practicality, with a large luggage shelf behind the seats. In addition to the coupé, a convertible, known as the V8 Vantage Roadster, was introduced later in that year. The V8 Vantage was initially powered by a 4.3 litre quad-cam 32-valve V8 which produced 380 bhp at 7,300 rpm and 409 Nm (302 lb/ft) at 5,000 rpm. However, models produced after 2008 had a 4.7-litre V8 with 420 bhp and 470 Nm (347 lbft) of torque. Though based loosely on Jaguar’s AJ-V8 engine architecture, this engine was unique to Aston Martin and featured race-style dry-sump lubrication, which enabled it to be mounted low in the chassis for an improved centre of gravity. The cylinder block and heads, crankshaft, connecting rods, pistons, camshafts, inlet and exhaust manifolds, lubrication system and engine management were all designed in house by Aston Martin and the engine was assembled by hand at the AM facility in Cologne, Germany, which also built the V12 engine for the DB9 and Vanquish. The engine was front mid-mounted with a rear-mounted transaxle, giving a 49/51 front/rear weight distribution. Slotted Brembo brakes were also standard. The original V8 Vantage could accelerate from 0 to 60 mph in 4.8 seconds before topping out at 175 mph. In 2008, Aston Martin introduced an aftermarket dealer approved upgrade package for power and handling of the 4.3-litre variants that maintained the warranty with the company. The power upgrade was called the V8 Vantage Power Upgrade, creating a more potent version of the Aston Martin 4.3-litre V8 engine with an increase in peak power of 20 bhp to 400 bhp while peak torque increased by 10 Nm to 420 Nm (310 lb/ft). This consists of the fitting of the following revised components; manifold assembly (painted Crackle Black), valved air box, right and left hand side vacuum hose assemblies, engine bay fuse box link lead (ECU to fuse box), throttle body to manifold gasket, intake manifold gasket, fuel injector to manifold seal and a manifold badge. The V8 Vantage had a retail price of GB£79,000, US$110,000, or €104,000 in 2006, Aston Martin planned to build up to 3,000 per year. Included was a 6-speed manual transmission and leather-upholstery for the seats, dash board, steering-wheel, and shift-knob. A new 6-speed sequential manual transmission, similar to those produced by Ferrari and Lamborghini, called Sportshift was introduced later as an option. An open-topped model was added to the range in 2006 and then in the quest for more power a V12 Vantage joined the range not long after.

During 2016, a handful of lucky customers were able to take delivery of one (or both) of a couple of very special versions of the Vantage offered, the GT8 and GT12, and an example of the latter was here. First of them was the Vantage GT12. This started out as the Aston Martin Vantage GT3 special edition when it was unveiled at the Geneva Motor Show 2015. The company said that they would only manufacture 100 cars. After a complaint from Porsche over the use of the “GT3” moniker, the car was renamed the Vantage GT12. It features a new iteration of the 6.0-litre V12 that produces 592 bhp and 461 lb/ft  of torque. It has a kerb weight of 1,535 kg (3,384 lb), and can accelerate from 0 to 60 mph in 3.5 seconds. There were sufficient external alterations that you would know that you were looking at something very special. For the Vantage GT8, which was launched a year later, Aston decided to make more cars – 150 of them, which was 50 more than the GT12. The GT8 features the same 4.7-litre V8 as found in the base Vantage but with power now increased to 440 bhp, and has a top speed of 190 mph (310 km/h). The GT8 is available with either a 6-speed manual or a 7-speed Sportshift II automated manual transmission, and has a kerb weight of 1,510 kg (3,329 lb), a 100 kg (220 lb) reduction over the V8 Vantage S.

A new generation of the Virage was introduced at the 2011 Geneva Motor Show by Aston Martin. The Virage capitalised on the technology from the DBS and united it with the comfort and refinement found in the DB9 and Rapide. The Virage was intended to sit in the narrow slot between the basic DB9 and the flagship DBS. Aston Martin announced that the second generation of the Virage would be discontinued after 18 months of production, as the distinctions between it, the DB9, and the DBS were simply too slim. The car has a 2-seat or 2+2 seating configuration. The Virage’s 5.9-litre AM11 V12 engine has a power output of 497 PS and 570 Nm (420 lb/ft) of torque. It is capable of accelerating from 0 to 100 km/h (62 mph) in 4.6 seconds, and has a top speed of 300 km/h (186 mph), while the Virage Volante is limited to 295 km/h (183 mph). The Virage was available in two bodystyles: Coupé or Volante (convertible). With only 1001 Aston Martin Virage produced, UK deliveries were 114 (right-hand drive) of which 22 were Coupés and 92 Volantes.

This version of the Vanquish started life as the Project AM310 Concept that was unveiled at the 2012 Concorso D’Eleganza at Villa D’Este on the shores of Lake Como, Italy. The concept car was based on the fourth generation VH platform. It included a tweaked version of Aston Martin’s familiar grille and headlight design and a more pronounced bulge in the bonnet – with the real One-77-inspired flourishes saved for the sides and the rear, the side vents run almost to the door handles (from One-77), new rear light design from One-77, and a 5.9-litre V12 engine that produced 550 PS. Aston Martin later announced that the concept would be put into production as the all new Aston Martin Vanquish. The exterior styling of the Vanquish is an evolution of the DBS with many styling cues such as the elongated side strakes being inspired by the Aston Martin One-77. The boot lid included an integrated rear spoiler designed to look as if it is impossible to make; this was done on the orders of Aston Martin Chief Executive, Dr. Ulrich Bez. The car has an exposed carbon fibre side skirt showing its all carbon fibre body. The Vanquish uses the new VH Generation IV platform which is lighter and uses more carbon fibre components than the VH Generation II platform used in the DBS. The car featured an all new interior based on the one found in the exclusive One-77. The standard interior was trimmed in hand stitched leather and alcantara and was available in a range of colours. The centre console features an revised infotainment system over the one found in the DBS. The car was available as either a 2-seater or 2+2. The Vanquish used an upgraded version of Aston Martin’s flagship 5.9-litre AM11 V12 engine called the AM28 with a power output of 565 bhp at 6,750 rpm and torque of 457 lb/ft at 5,500 rpm. The Vanquish can accelerate from 0 to 100 km/h (62 mph) in 4.1 seconds, and has a top speed of 295 km/h (183 mph). Like most Aston Martins, the engine is front mid-mounted for better weight distribution, with the power going to the rear wheels. The Vanquish has 51/49 front/rear weight distribution, and a kerb weight of 1,739 kg (3,834 lb). It uses a fully catalysed stainless steel exhaust system with active bypass valves. The Vanquish uses an updated Touchtronic II six-speed automatic gearbox. It was the first Aston Martin model to be available with launch control. The combined space of cabin and a boot that, at 368 litres, is more than 60% larger than that of the DBS. The brakes are ventilated carbon ceramic discs, 398 mm (15.7 in) six-piston callipers in the front and 360 mm (14.2 in) four-piston callipers in the rear. The suspension is a lightweight aluminium front subframe with hollow castings with independent double wishbones incorporating anti-dive geometry, coil springs, anti-roll bar, and monotube adaptive dampers in the front and independent double wishbones with anti-squat and anti-lift geometry, coil springs, anti-roll bar, and monotube adaptive dampers in the rear. It has a three-stage adjustable adaptive damping system including normal, sport and track modes. The tyres are Pirelli P Zeros, 255/ZR20 in the front and 305/30 ZR20 in the rear. The vehicle was unveiled in the London Film Museum, Covent Garden, followed by 2012 Monterey Car Week. Deliveries to UK and Continental Europe began in late 2012. In August 2014, Aston Martin revealed technical modifications to the Vanquish. The changes include a new eight-speed Touchtronic III gearbox and upgraded AM29 V12 engine that produces 568 bhp and torque of 465 lb/ft. The changes greatly enhanced performance, with an acceleration of 0 to 100 km/h (62 mph) in 3.6 seconds, and a top speed of 324 km/h (201 mph). In 2013, Aston Martin unveiled a convertible version of the Vanquish, called Volante. The Volante includes a full carbon fibre body, triple-skin lightweight fabric roof, 50% larger boot than its predecessor and the third generation Brembo 398 mm × 36 mm front and 360 mm × 32 mm CCM rear Carbon Ceramic Matrix (CCM) brake discs with six-piston front and four-piston rear brake callipers (from the One-77). The Vanquish Volante is 13% torsionally stiffer than the outgoing DBS Volante. The carbon fibre-skin of the Vanquish Volante was created by the engineering team at Aston Martin. The vehicle was unveiled at the 2013 Pebble Beach Concours d’Elegance. Deliveries to Europe began in late 2013. On 16 November 2016, Aston Martin announced the new Vanquish S model. The Vanquish S features the same AM29 V12 engine, with power now increased to 595 bhp, and a new aerodynamic package. The Vanquish S can accelerate from 0 to 100 km/h (62 mph) in 3.5 seconds, and the top speed remains unchanged at 201 mph (324 km/h). The starting price at launch was £199,950 and deliveries started in December 2016. Aston Martin also unveiled a convertible version of the Vanquish S called the Vanquish S Volante in 2017.

The Aston Martin Rapide is a sports saloon car, built from 2010 to 2020. It has four doors and four seats. It was first presented as a concept car at the North American International Auto Show in 2006 and the production version was shown at the 2009 Frankfurt Motor Show. The Rapide name is a reference to the Lagonda Rapide, a four-door, four-seater saloon produced by Lagonda, now a part of Aston Martin. The new Rapide is the company’s first 4-door fastback saloon since the Lagonda which was discontinued in 1990. The Rapide is based on the DB9 and is underpinned by the Aston Martin VH platform. The first cars rolled off the production line in May 2010, initially built at a dedicated plant at the Magna Steyr facility in Graz, Austria. The factory initially planned to build 2,000 cars per year, but production was relocated to England in 2012 after sales did not meet production targets. The Rapide is powered by a 5,935 cc  V12 engine, generating a maximum power output 477 PS and torque of 600 Nm (443 lb/ft). The car is rear-wheel drive and has a 6-speed Touchtronic II automatic transmission. The Rapide can attain a top speed of 303 km/h (188 mph), and can accelerate from 0 to 100 km/h (62 mph) in 5.2 seconds. The Rapide’s standard features include a tilt-telescoping steering wheel, bi-xenon headlamps and LED taillamps. Leather and walnut wood trim with metallic accents; power front seats with memory, cooling and heating systems; Bluetooth; satellite radio (US version only); with USB and iPod connectivity. Other standard features include a Bang & Olufsen 16-speaker sound system with two tweeters that rise from the dashboard on activation of the system. The Rapide was designed by stretching the design of the DB9 in order to accommodate an extra set of doors. Aston Martin design director, Marek Reichman has described a thoroughbred race horse as an inspiration, stating that he wanted muscles in the design to be visible through the skin. The side windows of the car were made to appear like a single unit by using a black B pillar. The roof was designed to be as low as possible so it would mimic the design language of Aston Martin’s model lineup. Due to the usage of swan doors and a low roof, the car is difficult for the accommodation of tall people. By comparison, the Porsche Panamera, a competitor of the Rapide, is 2.3 inches taller. The rear flanks of the car are wider than those on the DB9, thus smoothening the extended roof design. The rear fenders and a curvaceous design language prevent the car as being perceived as stretched. The car makes use of rear lights and diffusers from the Vantage while the front headlamps are unique to the model. Although they would find use on the later Vanquish and the facelift DB9. The Rapide S succeeded the standard Rapide in 2013. The AM11 V12 engine is upgraded and now has a power output of 558 PS and torque of 620 Nm (457 lb/ft). Performance improvements include a top speed of 306 km/h (190 mph) and acceleration from 0 to 100 km/h (62 mph) reduced to 4.9 seconds. Carbon dioxide emissions are reduced by 23g/km to 332g/km. The Rapide S received further revisions in 2014, with a new 8-speed Touchtronic III automatic transmission. It also used the AM29 V12 engine, with a power output of 560 PS and 630 Nm (465 lb/ft) of torque, resulting in an acceleration of 0 to 100 km/h (62 mph) in 4.4 seconds and an increased top speed of 327 km/h (203 mph).n June 2018, Aston Martin unveiled the high-performance iteration of the Rapide called the Rapide AMR. The 5.9-litre naturally aspirated AM29 V12 engine produces 603 PS and 630 Nm (465 lb/ft) of torque, courtesy of better air flow to the engine and new calibration software. The 8-speed automatic transmission has also received recalibration for better shift timing. The car now comes standard with Michelin Pilot Supersport tyres and 21-inch alloy wheels, the biggest wheels ever fitted to an Aston Martin. The new model features carbon ceramic braking system with six piston calipers at the front and four piston calipers at the rear featuring 400 mm and 360 mm brake rotors front and aft. The car features a new front grille, “sprout” fog lamps and side sills, rear diffuser and bootlid made from carbon fibre. The Rapide AMR can accelerate from 0–100 km/h (0–62 mph) in 4.4 seconds and can reach a claimed top speed of 330 km/h (205 mph). Interior options include a One-77 steering wheel, a personalised plaque along with logos and a variety of colour schemes. Production was limited to 210 examples only. Aston Martin opted to end its production by sub-contractor Magna Steyr in the middle of 2012, six years earlier than expected. Production of the car was also halted temporarily in May 2011. In the face of a diminishing market for luxury saloons, and to match output to shrinking sales, Aston Martin had to cut annual production from 2,000 to 1,250 in June 2011 – and was prepared to go as low as 500 annually. Rapide sales were a fraction of Aston Martin’s more popular Vantage and Vanquish nameplates. Production of the Rapide ended in 2020 with the Rapide AMR as the final variant.

The Aston Martin DB11 is a two-door grand touring car. It was available as both a coupe and a convertible, the latter known as the “Volante”. The British carmaker Aston Martin produced the DB11 from 2016 to 2023 when it was replaced by the DB12. The DB11 succeeded the DB9, which the company made between 2004 and 2016. Designed by Marek Reichman, who became lead designer in May 2005, the DB11 debuted at the Geneva Motor Show in March 2016. The first model of Aston Martin’s “second-century plan”, the DB11—like its predecessor and its platform siblings—incorporates aluminium extensively throughout its body. Official manufacture of the DB11 began at the facility in Gaydon, Warwickshire, in September 2016. Two engine configurations of the DB11 were available: a 4.0-litre V8-engine model produced by Mercedes-AMG and a 5.2-litre V12-engine model produced by Aston Martin. The Volante version of the DB11 was introduced in October 2017. In 2018, Aston Martin and its racing division replaced the DB11 V12 with the DB11 V12 AMR, which included an increased engine output. The V8-powered model also received an enhancement in engine performance in 2021. Aston Martin began producing the DB9—a grand touring car—in January 2004 at the facility in Gaydon, Warwickshire. It was the first car built on the vertical–horizontal platform—a design in which all vehicles that used it extensively incorporated aluminium throughout their construction. This platform formed the basis of the Vantage in 2005, the DBS in 2007, the Rapide in 2010, the Vanquish in 2012 and the Lagonda Taraf in 2014. In 2015, Aston Martin announced that the DB9’s successor would be named the “DB11”. The upcoming range, known as the “second-century plan”, which the DB11 was a part of, was to introduce a refreshed design approach directed by Marek Reichman, whom Aston Martin appointed lead designer in May 2005. Insider reports indicated that this model range aimed to address critiques of the existing lineup by emphasising distinctive differences among the models, aligning them more closely with the prominent Italian luxury automobile manufacturer Ferrari. Manufacture of the DB9 officially ended in July 2016, after a twelve-year production run during which 16,500 units had been made. The DB11 debuted at the Geneva Motor Show in March 2016. Official manufacture of the DB11 began on 28 September 2016 at the facility in Gaydon, Warwickshire. To demonstrate his commitment to quality, Aston Martin’s then-CEO, Andy Palmer, personally inspected the first 1,000 cars. Similar to its predecessor, the DB11 is based upon a platform—which it shares with the 2018 model Vantage and the DBS Superleggera—that extensively incorporates aluminium throughout its construction. The chassis, in comparison to the DB9, is lighter and stiffer. Its body panels are made of both aluminium and composite materials, and the bonnet is a single-piece unit. Together, the car’s flat underbody, rear diffuser and sizable front splitter manage airflow beneath the DB11, minimising lift. The DB11 features an AeroBlade that captures high-speed air at the C-pillars and channels it through ducts under the bodywork, exiting through slots in the boot lid. This system mimics the effects of a large rear spoiler, reducing drag without added bodywork. An extendable active spoiler enhances the AeroBlade’s efficiency at high speeds. The DB11 has been described as both a sports car and a grand tourer. It is a two-door coupe that was available only in a four-passenger seating configuration. The DB11 has a rear-wheel drive layout with a front-mid-engine placement and exclusively uses a rear-mounted, eight-speed automatic transmission made by the technology manufacturing company ZF Friedrichshafen. Each DB11 was handcrafted, involving approximately 600 engineers and taking around 250 hours to complete. The Vanquish features anti-roll bars and double wishbone suspension supported by coil springs. There are three different drive modes available for both the drivetrain and chassis: normal—suitable for daily driving; sport—offering enhanced precision; and Sport+—intensifying the characteristics of the sport mode. The DB11 has a near-perfect weight distribution of 51 per cent at the front and 49 per cent at the rear. According to the magazine Motor Trend, the DB11 has a combined fuel economy figure of 17 miles per US gallon (14 L/100 km; 20 mpg‑imp). According to Auto Express, the car has a CO2 emission rating of 270 g/km. The doors of the DB11, like the DB9, are swan-hinged. The infotainment system operates on an eight-inch liquid-crystal display accessed via a rotary controller or an optional touchpad. Each DB11 comes with a 400-watt audio system, USB playback, SiriusXM satellite radio, and a Wi-Fi hotspot with iPhone integration. Upgrades were available for a 700-watt sound system or a 1,000-watt Bang & Olufsen unit. The DB11 has a boot capacity of 270 litres (9.5 cu ft). The AE31 twin-turbocharged V12 engine, with a 5,204 cc displacement, was featured in the initial version of the DB11. It produces a power output of 600 bhp at 6,500 rpm and a torque output of 700 Nm (520 lb/ft) between 1,500–5,000 rpm, sufficient to give the car a zero to 60 mph (97 km/h) acceleration of 3.6 seconds and a maximum speed of 200 miles per hour (320 km/h). Aston Martin began the development of the V12 engine in the summer of 2012 under the leadership of Brian Fitzsimons. The project progressed quickly; initial test firing began in October 2012, and it received approval for production in January 2013. The new V12 engine continues to use conventional fuel injection rather than direct injection due to concerns about the potential increase in particulate emissions associated with direct injection petrol engines. The DB11 V12 can run the quarter mile in 11.7 seconds. In May 2018, Aston Martin introduced the DB11 Aston Martin Racing (AMR) version, which succeeded the DB11 V12. The DB11 AMR offers enhanced performance capabilities compared to its predecessor. The previous DB11 V12 had been in production for eighteen months. The updated DB11 AMR produces a power output of 630 bhp at 6,500 rpm and a torque output of 700 Nm (520 lb/ft) at 1,500 rpm, sufficient to give the car a zero to 60 mph (97 km/h) acceleration of 3.7 seconds and a maximum speed of 208 mph (335 km/h). Its shift programming has been revised, its rear suspension is firmer and stiffer, and its twenty-inch forged wheels are 3.5 kilograms (7.7 lb) lighter. Aston Martin introduced a limited edition of 100 DB11 AMR Signature Edition cars at the beginning of production, featuring a Stirling Green paint scheme with lime green accents. It has a zero to 60 mph (97 km/h) acceleration of 3.5 seconds—0.2 seconds faster than the base AMR. Deliveries started in the second quarter of 2018. In July 2021, Aston Martin announced that the AMR name would no longer be used for the V12-powered DB11 as part of their updated model lineup. The original V12 model was supplemented by an entry-level V8 version in June 2017. Powered by a 4.0-litre Mercedes-Benz M177 twin-turbocharged V8 engine developed by Mercedes-AMG, this configuration achieves a weight reduction of 115 kilograms (254 lb) compared to the V12 variant, resulting in a total kerb weight of 1,760 kilograms (3,880 lb). In contrast to the V12 model, the DB11 V8 has a weight distribution of 49 per cent at the front and 51 per cent at the rear. The V8 engine delivers 503 bhp and 675 Nm (498 lb/ft), providing the car with a zero to 60 mph (97 km/h) in four seconds and a top speed of 187 mph (301 km/h). In July 2021, Aston Martin revealed an upgraded version of the DB11 V8. The power output was increased to 528 bhp, allowing the car to accelerate from zero to 60 mph (97 km/h) in 3.9 seconds and reach a higher top speed of 192 miles per hour (309 km/h). In October 2017, Aston Martin introduced the DB11 Volante, a convertible version of the DB11. The Volante has a weight distribution of 47 per cent at the front and 53 per cent at the rear, and is powered by the same 4.0-litre twin-turbocharged V8 engine as the DB11 V8 coupe, albeit with more torque, at 696 Nm (513 lb/ft). The DB11 Volante can accelerate from zero to 60 mph (97 km/h) in 4.1 seconds and possesses a maximum speed of 187 mph (301 km/h). The additional lower body strengthening and the electric roof mechanism in this version increase the weight by approximately 110 kilograms (240 lb). The DB11 received mostly positive reviews. Production of the DB11 ended at the end of June 2023. It was replaced by the DB12, which was unveiled at the 2023 Cannes Film Festival.

The latest and still current Aston Martin Vantage was unveiled on 21 November 2017 with production starting in June 2018, replacing the previous model which had been in production for 12 years. It introduced a new styling direction but this was not universally well received and the car had a hefty price increase over its predecessor. Muted press enthusiasm did not help and sales have been disappointing. Aston Martin have continued to develop the model with a number of new versions introduced, to try to improve demand. The Vantage AMR is a track-focused variant of the Vantage. The main highlight of the model is the replacement of the ZF 8-speed automatic transmission with a dog-leg Graziano Trasmissioni 7-speed manual transmission previously used on the V12 Vantage S. The AMR also comes with a driver-selectable AMSHIFT system which controls the throttle during gear shifting. A new limited-slip differential ensures linear delivery of power. The power-band of the engine is wider and the unit is designed to deliver 625 Nm (461 lb/ft) of torque from 2,000 rpm to 5,000 rpm. The use of a manual transmission and carbon-ceramic brakes reduce the weight by 95 kg (209 lb). New adaptive dampers with the section of Sport, Sport + and Track modes improve handling. Performance figures include a 0–97 km/h (60 mph) acceleration time of 3.9 seconds, half a second more than the standard Vantage while the top speed remains the same as the standard model. Visual changes include 20-inch forged wheels as available on the Rapide AMR, new carbon fibre side vents and cooling vents present on the hood a sports exhaust system with quad tailpipes and racing bucket seats. Production of the AMR will be limited to 200 units worldwide. Available exterior colours for the AMR include Sabiro Blue, Pnyx Black, China Grey and White Stone. The final 59 cars will be finished in a Sterling Green exterior colour with Lime accents and will pay homage to the 1959 24 Hours of LeMans victory of Aston Martin. Once the production of the AMR ceases, the 7-speed manual transmission will become available on the standard Vantage. The vehicle went on sale in May 2019, with delivery set to begin in Q4 2019. Revealed in February 2020, the Vantage Roadster is a convertible version of the V8 Coupe with a fabric roof. The roof claimed to be the fastest of any automotive automatic convertible system, takes 6.7 seconds to lower and 6.8 seconds to raise and can be operated at speeds of up to 50 km/h (31 mph). The Vantage Roadster has a dry weight of 1,628 kg (3,589 lb). The F1 Edition is a version of the V8 Coupe and V8 Roadster commemorating Aston Martin’s return to Formula One after 61 years. The car features a fixed rear wing at the back, increased engine power to 535 PS (528 bhp), a top speed of 314 km/h (195 mph), new 21-inch wheel rims, and a 0–100 km/h (0–62 mph) acceleration time of 3.5 seconds. The car is available in three colours: Aston Martin Racing Green, Jet Black, and Lunar White. A convertible version called the Roadster is also available. Delivery began in May 2021.

The Aston Martin DBS Superleggera, also sold as the Aston Martin DBS, is a grand touring car produced from 2018 to 2024. In June 2018, Aston Martin unveiled the car as a replacement to the second-generation Vanquish. It is based on the DB11 V12, but featuring modifications that differentiate it from the DB11 lineage. The DBS name was previously used for a model built from 1967 to 1972 and for the DB9-based DBS between 2007 and 2012. In addition, the car also uses the Superleggera name which is a reference to Carrozzeria Touring Superleggera, who helped Aston Martin develop their lightest grand tourers in the 1960s and 1970s. In September 2024, Aston Martin announced the third-generation Vanquish as the successor of the DBS Superleggera. The front of the DBS features a new front bumper, with a larger centre grille compared to the DB11, for improved engine cooling, along with two air extractors on the sides to cool the brakes and two vents on the hood that aid in the engine cooling process. The 5.2-litre twin-turbocharged V12 engine, which is cast and manufactured at Grainger & Worrall in the United Kingdom before being shipped to the Aston Martin engine plant in Cologne for assembly, is rated at 725 PS at 6,500 rpm and 900 Nm (664 lb/ft) of torque from 1,800–5,000 rpm. In order to optimise the centre of gravity and weight distribution, the engine has been positioned as low and as far back in the chassis as possible. The DBS Superleggera features the new ZF 8HP95 transmission with a shorter final-drive ratio of 2.93:1, in contrast to the DB11’s 2.70:1. Chassis-wise, it also comes with torque vectoring and a mechanical limited slip differential for more focused track performance. The car also features many of the same aerodynamic features first seen on the DB11, including Aston Martin’s Aeroblade system, but refines aerodynamics with an F1-inspired double-diffuser that helps the car generate 397 lb (180 kg) of downforce – the highest figure ever for a series production Aston Martin. A new quad-pipe titanium exhaust system improves engine sound, while the usage of carbon fibre in major areas of the car lowers the weight down to 1,693 kg (3,732 lb). The DBS Superleggera can accelerate from 0–100 km/h (62 mph) in 3.4 seconds, and 0–161 km/h (100 mph) in 6.4 seconds. The car can also accelerate from 80–161 km/h (50–100 mph) in 4.2 seconds at fourth gear and can attain a top speed of 340 km/h (211 mph). Three driving modes are available: GT, Sport, and Sport Plus which adjust the car’s responsiveness. A Volante (convertible) model of the DBS was unveiled in April 2019. It has nearly identical performance and the same engine and transmission as the coupé but comes with an eight-layer soft top with eight colour options. For the first time on an Aston Martin automobile, the windshield surround is available in carbon fibre as well as the rear tonneau cover. There were a number of limited edition versions produced, too, in very small quantities.

Also here were examples of the DBX, Aston’s offering in the super-SUV sector.

The Aston Martin Valkyrie (also known by its code-names as AM-RB 001 and Nebula) is a limited production hybrid sports car collaboratively built by British automobile manufacturers Aston Martin, Red Bull Racing Advanced Technologies and several other parties. The sports car is a product of collaboration between Aston Martin and Red Bull Racing to develop a track-oriented car entirely usable and enjoyable as a road car, conceived by Adrian Newey, Andy Palmer, Christian Horner, and Simon Spoule. Adrian Newey, who is Red Bull Racing’s Chief Technical Officer, aided in the design of the car. The original codename was Nebula, an acronym for Newey, Red Bull and Aston Martin. The name AM-RB 001 was chosen as the final codename, and was decided since Aston Martin and Red Bull Racing had collaborated all throughout the project. AM stands for Aston Martin, and RB stands for Red Bull. 001 may be a reference to it being the first production car the two have collaborated on. In March 2017, Aston Martin revealed that the car would be named Valkyrie, after the Norse mythological figures. According to Red Bull, the name was chosen to continue the tradition of “V” nomenclature of Aston Martin’s automobiles and to distinguish the vehicle as a high-performance car (the “V” was used as the distinguishing factor). The Aston Martin Valhalla, which is known as “Son of Valkyrie”, likewise has its origin in the mythological location Valhalla. A show car was initially unveiled to the public in order to give the public an idea of its design. The design was in a near-production-ready form. The exterior of the car is extremely aerodynamic for a sports car, with an extensively open underfloor, that works on the principle of the Bernoulli and Venturi effects and is capable of producing 18,000 N (1,800 kgf) of downforce at high speed (See Ground effect (cars)). Gaps on top of the car (for example, above the front axle and the roof intake) and a large front splitter aid in generating downforce. The wheels are also designed to manage the airflow and be as light as possible at the same time. The interior design was leaked online on 20 June 2017 and gave a preview of the car’s design. The interior has no gauge cluster, but rather a collection of screens. By the left and right corners are the screens for the camera side mirrors. One screen sits at the top of the center console, which may have a collection of live vehicle information, and regular vehicle controls, but this is not confirmed. A screen is used on the race-inspired steering wheel and acts as the driver gauge cluster. Dials and switches sit beside the wheel screen to allow for easier changes without driving interruption. The seats, formed from hollow carbon fibre straight into interior perimeter, are bucket variants, and have two seat belts for each car seat. Because of the extremely small interior and doors (which are practically roof-only hatches), each seat is designed specifically for the owner’s body shape through 3D scanning. A removable steering wheel provides slightly more space for entry and exit. In February 2017, Aston Martin revealed most of the vehicle’s specifications. The final specifications were revealed later in the year. Several manufacturers (other than Aston Martin and Red Bull) have taken part in the Valkyrie’s construction, those being Cosworth, Ricardo, Rimac Automobili, Multimatic, Alcon, Integral Powertrain Ltd, Bosch, Surface Transforms, Wipac, HPL Prototypes and Michelin. The car contains a 6.5-litre naturally-aspirated V12 engine tailored by Cosworth, which produces around 746 kW (1,000 hp) at 10,500 rpm, with a redline of 11,100 rpm. This will make it the most powerful naturally-aspirated engine ever to be fitted to a production road car. With a KERS-style boost system akin to those fitted to F1 cars, the Aston Martin Valkyrie’s hybrid system has been developed by two main technical partners; Integral Powertrain Ltd, who supplied the bespoke electric motor, and Rimac for the lightweight hybrid battery system. As a result, the full hybrid system contributes an additional 120 kW (160 bhp) of power and a further 280 Nm of available torque with the certified max power output of Aston Martin Valkyrie standing at 865 kW (1,160 hp) @ 10,500rpm. Equally, with the full hybrid system, peak torque will stand at 900 Nm (664 lb/⋅ft) @ 6,000 rpm. At the same time the power output figures were released, the weight was announced to be 1,030 kg (2,271 lb), surpassing the intended 1:1 power-to-weight ratio with 840 kW (1,126 hp) per ton. The car can accelerate to 100 km/h (62 mph) from a standstill in a time of 2.6 seconds. The exhausts exit at the top of the car, near the engine, similar to those of Formula One cars and the Porsche 918 Spyder. Bosch supplies the Valkyrie’s ECU, traction control system, and ESP. The braking system is provided by Alcon and Surface Transforms. The front and rear lights are manufactured by Wipac. The car has all-carbon fibre bodywork and is installed with a carbon fibre Monocell from manufacturer Multimatic. Michelin supplies the Valkyrie with the company’s high-performance Sport Cup 2 tyres, having sizes of 265/35-ZR20 at the front and 325/30-ZR21 at the rear. The wheels are constructed out of lightweight magnesium alloy (20 in (510 mm) front, 21 in (530 mm) rear) with race-spec centre-lock wheel nuts to reduce mass. In 2020, after Red Bull Racing’s Red Bull Racing RB16 had its first shakedown in Silverstone Circuit, drivers Max Verstappen and Alexander Albon drove the car around the track.

AUDI

The Audi R8, based on the Audi Le Mans quattro concept car (designed by Frank Lamberty and Julian Hoenig) first appeared at the 2003 International Geneva Motor Show and the 2003 Frankfurt International Motor Show. The R8 road car was officially launched at the Paris Auto Show on 30 September 2006. There was some confusion with the name, which the car shares with the 24 Hours of Le Mans winning R8 Le Mans Prototype (LMP). Initial models included the R8 4.2 FSI coupé (with a V8 engine) and R8 5.2 FSI coupé (with a V10 engine). Convertible models, called the Spyder by the manufacturer, were introduced in 2008, followed by the high-performance GT model introduced in 2011. The Motorsport variants of the R8 were also subsequently introduced from 2008 onwards. An all-electric version called the e-Tron started development but would only reach production stage when the second generation model would be introduced. 6-time 24 Hours of Le Mans winner Jacky Ickx described the R8 as “the best handling road car today” and the car was well received by everyone who drove it. The car received a facelift in 2012 and a new model called the V10 Plus was now added to the range. Production of the Type 42 ended in August 2015

This is the second generation R8. Launched at the 2015 Geneva Motor Show and is based on the Modular Sports System platform shared with the Lamborghini Huracan. The development of the Type 4S commenced in late 2013 and was completed in late 2014. Initial models included the all-electric e-Tron and the V10 5.2 FSI along with the V10 plus. Unlike its predecessor, there was no manual transmission available and the entry-level V8 trim was also dropped. In 2016, the convertible (Spyder) variant was added to the line up which was initially available in the base V10 trim. In mid-2017, the high performance V10 plus Spyder was added to the range. A rear-wheel-drive model called the R8 RWS was introduced. In 2018, the R8 received a mid-cycle refresh with mechanical and exterior changes. The newer and more aggressive design language carried over from famous Audi models of the past and its appearance is slightly more angular up front. Some of the aerodynamic features such as the front aeroblades are shared with the Lamborghini Huracàn. The refreshed model had substantial performance improvements over its predecessor. The base R8 got a power boost from 532 hp to 562 hp, while the V10 Plus was renamed V10 Performance Quattro and the engine saw a power increase by 10 hp,  now up to 612 hp.

BENTLEY

Oldest of a display of Bentleys that were to be found in the courtyard along with a lot of Rolls Royce models were several examples of cars sometimes referred to as the “Derby” Bentley. These were produced after the acquisition of Bentley by Rolls-Royce, in 1934, at which point the focus of the brand shifted to the production of large and elegant tourers. The cars retained the famous curved radiator shape based on earlier Bentley models, but in all meaningful respects they were clearly Rolls-Royces. Although disappointing some traditional customers, they were well received by many others and even W.O. Bentley himself was reported as saying that he would “rather own this Bentley than any other car produced under that name.” The Rolls-Royce Engineer in charge of the development project, Ernest Hives (later Lord Hives), underlined the Rolls-Royce modus operandi in a memo addressed to company staff “our recommendation is that we should make the car as good as we know how and then charge accordingly.” At a time when the Ford 8 could be purchased new for £100, an early Bentley 3½ Litre cost around £1,500 (equivalent to £6400 vs. £96,000 today), putting it beyond the reach of all but the wealthiest consumers. Despite not being a car of remarkable outright performance, the car’s unique blend of style and grace proved popular with the inter-war elite and it was advertised under the legend the silent sports car. Over 70% of the cars built between 1933 and 1939 were said to have still been in existence 70 years later. Although chassis production ceased in 1939, a number of cars were still being bodied and delivered during 1940. The last few were delivered and first registered in 1941. The 3.5 litre came first. Based on an experimental Rolls-Royce project “Peregrine” which was to have had a supercharged 2¾ litre engine, the 3½ Litre was finally fitted with a less adventurous engine developed from Rolls’ straight-6 fitted to the Rolls-Royce 20/25. The Bentley variant featured a higher compression ratio, sportier camshaft profile and two SU carburettors on a crossflow cylinder head. Actual power output was roughly 110 bhp at 4500 rpm, allowing the car to reach 90 mph. The engine displaced 3669 cc with a 3¼ in (82.5 mm) bore and 4½ in (114.3 mm) stroke. A 4-speed manual transmission with synchromesh on 3rd and 4th, 4-wheel leaf spring suspension, and 4-wheel servo-assisted mechanical brakes were all common with other Rolls-Royce models. The chassis was manufactured from nickel steel, and featured a “double-dropped” layout to gain vertical space for the axles and thus keep the profiles of the cars low. The strong chassis needed no diagonal cross-bracing, and was very light in comparison to the chassis built by its contemporary competitors, weighing in at 2,510 pounds (1,140 kg) in driveable form ready for delivery to the customer’s chosen coachbuilder. 1177 of the 3½ Litre cars were built, with about half of them being bodied by Park Ward, with the remainder “dressed” by other coachbuilders like Barker, Carlton, Freestone & Webb, Gurney Nutting, Hooper, Mann Egerton, Mulliner (both Arthur and H J), Rippon, Thrupp & Maberly, James Young, Vanden Plas and Windovers in England; Figoni et Falaschi, Kellner, Saoutchik and Vanvooren in Paris; and smaller concerns elsewhere in UK and Europe. Beginning in March, 1936, a 4¼ Litre version of the car was offered as replacement for the 3½ Litre, in order to offset the increasing weight of coachwork and maintain the car’s sporting image in the face of stiff competition. The engine was bored to 3½ in (88.9 mm) for a total of 4257cc. From 1938 the MR and MX series cars featured Marles steering and an overdrive gearbox. The model was replaced in 1939 by the MkV, but some cars were still finished and delivered during 1940-1941. 1234 4¼ Litre cars were built, with Park Ward remaining the most popular coachbuilder. Many cars were bodied in steel rather than the previous, more expensive, aluminium over ash frame construction.

Oldest of the post cars was this R Type. Announced in May 1946, as the mark VI and produced from 1946 to 1952 it was also both the first car from Rolls-Royce with all-steel coachwork and the first complete car assembled and finished at their factory. These very expensive cars were a genuine success, long-term their weakness lay in the inferior steels forced on them by government’s post-war controls. The chassis continued to be supplied to independent coachbuilders. Four-door Saloon, two-door saloon and drophead coupe models with bodies by external companies were listed by Bentley along with the Bentley-bodied saloon. This shorter wheelbase chassis and engine was a variant of the Rolls-Royce Silver Wraith of 1946 and, with the same standard steel body and a larger boot became the cautiously introduced Silver Dawn of 1949. The same extended-boot modification was made to the Mark VI body in 1952 and the result became known as the R type Bentley.

A close relative of the Rolls Royce Silver Cloud, the S Type was first revealed in April 1955. It represented a complete redesign of the standard production car, the R Type. It was a more generously sized five- or six-seater saloon with the body manufactured in pressed steel with stressed skin construction, with the doors, bonnet and boot lid made of aluminium. The external appearance was very different, although the car still had the traditional radiator grille. Compared to the outgoing R Type, the new model had a three inch longer wheelbase, was lower of build without reducing headroom and with an enlarged luggage boot, softer suspension with electrically operated control of rear dampers, lighter steering and improved braking. The engine, still a clear descendants of the one originally used in the Rolls-Royce Twenty from 1922 to 1929, had its capacity increased to 4887cc, and a four-speed automatic gearbox was standard, with the ability to select individual ratios if desired, which was enough to give the Bentley a top speed of just over 100 mph and 0 – 60 acceleration times of around 13 seconds. Standard and from 1957, long wheelbase saloons were offered and  some were sent to the coachbuilders for alternative bodies to be fitted. An upgrade in 1959, creating the S2, saw the installation of a new V8 engine, and in 1962, the S3 cars gained four round headlights. 3072 S Types were made, 145 of them with coachbuilt bodies as well as 35 of the long wheelbase cars, before the model was replaced by the new T Type in 1965.

This is a 1957 S1 with a James Young 2 door coupe body and was the Geneva Motor Show car in 1957. It is believed that James Young only built three of these 2 door cars but they were a third more expensive than the standard 4 door car and as a result were hard to sell.

The Bentley T-series is a luxury automobile produced by Bentley Motors Limited from 1965 to 1980. It was announced and displayed for the first time at the Paris Motor Show on 5 October 1965 as a Bentley-badged version of the totally redesigned Rolls-Royce Silver Shadow. The Bentley T series was available as a four-door saloon and as a long wheelbase four-door saloon. A small number of two-door saloons were built with coachwork by James Young and Mulliner Park Ward and a two-door convertible with coachwork by Mulliner Park Ward was introduced in September 1967. A total of 2,336 examples were produced. The T series was the first unibodied Bentley, and was totally different from its predecessor the S series.[2] It featured a new steel and aluminium monocoque body with subframes to mount the engine and suspension. While smaller overall, it had more passenger room, particularly in the rear compartment, yet more luggage space. Overall the car was 7 inches (18 cm) shorter, 5 inches (13 cm) lower, 3+1⁄2 inches (9 cm) narrower, and 150 pounds (68 kg) lighter than the S. Because of being fitted with the traditional round-shouldered “Bentley” style front grille – its sole material styling difference from the Rolls-Royce Silver Shadow – it was also somewhat lower at bonnet height, giving it a slightly more assertive look. The ‘T’ also featured independent suspension on all four wheels with automatic height control according to loading. Other major improvements included disc brakes on all wheels (with a triplicate hydraulic braking system patented from Citroën that also supplied pressure for the self leveling suspension); new and lighter power steering, improved automatic transmission, eight-way adjustable electric front seats, and a larger fuel tank. The engine received a redesigned cylinder head that allowed a speed increase to 118 miles per hour (190 km/h). In October 1966, the T saloon’s pretax ‘list price’ of £5425 was £50 less than the Silver Shadow. The formerly more sporting image of Bentley motor cars differing from Rolls-Royces was long gone and far from being renewed by the time the Bentley T was introduced. Effectively, the two were indistinguishable. The T was upgraded to the “T2” in 1977, which featured rack and pinion steering, improved air conditioning, rubber-faced bumpers, a new fascia and, for non-federalized cars, a front air dam. Bosch CIS Fuel Injection was introduced for late 1979 and 1980 models for the US and other markets, similarly to the Rolls-Royce Silver Shadow II. The T2 was discontinued in 1980.

Although the Turbo models claimed the limelight of the 1980s and 1990s, the lesser versions of the car sold well, too. Several different version of what started out simply as the Mulsanne, a badge-engineered version of the Rolls-Royce Silver Spirit were offered. The Eight was Bentley’s “entry-level” offering from 1984 until 1992. Distinguished mainly by a wire-mesh grille radiator instead of vertical slats, the Eight also had somewhat less equipment than the similar Mulsanne on which it was based. This brought the introductory price to under the psychologically important £50,000 mark at the time of introduction, £6,000 less than the Mulsannne. A firmer suspension offered slight handling improvements. The Eight was so popular that sales expanded from the original UK market to Europe and the United States. The Eight was introduced with cloth upholstery, steel wheels, and a mesh grille that was simpler than the slatted grille of the Mulsanne. Fuel injection and anti-lock brakes were added in 1986, leather upholstery and power memory seats were added in 1987, and automatic ride height adjustment was added in 1990. In Britain, catalytic converters became optional in 1990 – although they had been available long before in markets where such were required. The three-speed automatic transmission was replaced by a four-speed transmission in August 1992. The Bentley Brooklands was introduced in 1992 as a replacement for the Bentley Mulsanne S and Bentley Eight models. It was intended as a slightly cheaper alternative to the Bentley Turbo R, featuring the same styling, underpinnings and the Rolls-Royce 6.75-litre V8 engine, but without the more powerful model’s turbocharger. The Brooklands continued Bentley’s relatively angular design theme, which was also used on contemporary Rolls-Royce vehicles, throughout the 1980s and early 1990s. The exterior design featured the classic Bentley waterfall grille as well as dual headlights with wraparound parking lights. As in many Bentley and Rolls-Royce vehicles, the Brooklands also featured the trademark descending bootlid and chrome B-pillars. The interior remained relatively unchanged from previous Bentley models, with more curvaceous design elements surrounding the leather-wrapped centre console. The steering wheel and interior door panels remained largely unchanged; the major change arrived in the form of relocating the gear selector to the centre console – for decades the standard practice among R-R and Bentley models utilised a steering column mounted selector. The interior continued to be surrounded by ample woodgrain which featured engraved, lighter-coloured outlines on the door panels.

The Arnage, a twin of the Rolls-Royce-branded sibling, the Silver Seraph, was introduced in the Spring of 1998, the first entirely new designs for the two marques since 1980. This is a large car: over 5.4 metres (212 in) long, 1.9 metres (75 in) wide, and has a kerb weight of more than 2.5 metric tonnes. For a brief period it was the most powerful and fastest four-door saloon on the market. In a complete switch from tradition, whilst these cars had bodies built at the Crewe factory, the then owner, Vickers, decided that the car would be powered by engines built elsewhere. A number of potential engines were examined, including the GM Premium V engine, and a Mercedes-Benz V8 engine, before, in late 1994, Vickers selected a pair of BMW power plants. It was decided that the Rolls-Royce model would use BMW’s naturally aspirated V12 engine while the more-sporting Bentley model would use a special twin-turbo version of the 4.4-litre BMW V8, which was developed by Vickers subsidiary, Cosworth Engineering. On its introduction in the spring of 1998, the Arnage was available as a single model with the this 4,398cc twin turbo developing some 354 PS (349 bhp) and 420 lb·ft. During the takeover battle in 1998 between BMW and Volkswagen Group for ownership of Rolls Royce and Bentley Motors, BMW had threatened to stop supply of their engines if Volkswagen Group won. While the threat was later withdrawn in conjunction with BMW acquiring the right to manufacture the Rolls Royce marque at a new location, it was clear that Volkswagen could not accept the business and reputation risks associated with having their rival as a long-term business partner. Furthermore, customers were nervous about engine and part availability (of which there turned out to be no issue) and orders for new cars dropped precipitously. Volkswagen’s response was to prepare the old pushrod 6.75-litre 16-valve engine from the Turbo R for the Arnage, designed for the lighter and smaller BMW 32-valve V8 unit. Coupled with an outdated 4-speed automatic, the engine was extremely thirsty, and would not meet government-imposed emissions standards without hasty modifications. The revised version of the car was launched as the Arnage Red Label in October 1999. At the same time, but without the fanfare, Bentley made several minor modifications to the original BMW engined cars, and designated them as the “Arnage Green Label” for the 2000 model year. As part of the modification process, both Red and Green Label cars received stiffer body shells and larger wheels and brakes. The stiffer body shell was needed because of the extra weight of the British engine. The larger brakes were needed for the same reason. Despite the larger brakes, braking performance worsened with the extra weight of the 6.75 engine. The braking performance of the ’99 Green Label from 70–0 was 172 feet while the later Arnage T’s performance was 182 feet from the same speed. The PR department at Bentley pointed to customer demand as the driving force behind the reversion to the old two valve per cylinder 6.75-litre unit for the Red Label. This explanation appears to have been acceptable to all but a few of the motoring press who welcomed the return of the old unit after criticising the BMW motor as at best insipid and, at worst, underpowered. In reality, the outgoing BMW-powered Arnage was technically more modern, considerably more fuel efficient, and had 32 valves with double overhead camshafts, twin-turbo and Bosch engine management technology – as opposed to 16-valve, single turbo and a pushrod motor with less advanced engine management. The Red Label’s increase in motive power shaved less than a second of the zero to 60 mph time. However, the BMW twin turbo unit remained noticeably more agile and responsive from a driver’s perspective, due to its more responsive DOHC engine, better weight balance(maintaining a 51.1/48.9 weight distribution) and almost 600 lb (270 kg) lower curb weight. Ultimately the Green Label was more reliable and significantly less expensive to service in the long term. The key limiting factor of the BMW engine’s output was the ZF 5HP30 transmission which was not rated to handle more than the 413 lb·ft torque that the twin turbo engine was tuned to produce. In total only seven Arnage Green Label units were built, all of which were left-hand-drive versions. There was a final series of vehicles built in 2000 with the 4.4-litre BMW engine designated the Arnage Birkin, of which 52 units were produced and are distinguishable by their three-dial as opposed to five-dial instrument centre dashboard configuration. A long-wheelbase version of the Red Label was launched at the North American International Auto Show in 2001. The Green Label ended production in 2000. The Red Label models were replaced in 2002. In 2001, the Arnage RL, a long-wheelbase model, 9.8 in longer than the Arnage, was launched, the extra length added to the car at its rear doors and its C-pillar. With the standard Arnage model, the rear wheel wells butt up against the rear door frames, but with the RL they are a few inches further back. The overall effect is a larger rear area inside the car. Available only as a bespoke “Mulliner” model, each RL was customised to the desires of the buyer. The RL, however, was also the first of a new series of Arnages which would finally cure the Bentley Arnage of the reliability and performance deficiencies experienced following its forced deprivation of the modern BMW engines it was designed to use. The RL would also present a credible challenge to BMW’s attempts to revive the Rolls-Royce brand with its planned new model, the Phantom. The RL’s introduction saw the introduction of an entirely reworked version of the 6.75-litre V8 engine. Where the engine used in the Red Label was a quickly and less-than-completely-satisfactorily modified version of the Turbo RT’s unit, the RL featured an entirely reworked version of the old 6.75-litre V8. More than half of the engine’s parts were completely new, with Bosch Motronic ME7.1.1 engine management replacing the old Zytek system, and two small Garrett T3 turbochargers replacing the single large T4. This new engine developed 405 PS (399 bhp) and 616 lb·ft, and was said to be capable of meeting all future emissions requirements. Finally, the Arnage was powered by a modern twin-turbo unit with state-of-the-art electronic management system similar to the originally Cosworth-BMW unit developed for the Arnage in 1998. Perhaps ironically, what was essentially a new engine developed by Volkswagen Group engineers for the RL in 2001, was now producing the same sort of power as the original BMW V8 4.4 engine used in the first Arnage in 1998. Unfortunately, the development and testing of the revisions to the new engine were rushed by VW to meet regulatory requirements. As a result, the camshafts are prone to failure requiring extensive repair work to remedy In 2002, Bentley updated the Red Label as the series two Arnage R. This model was launched to contrast the Arnage T, which was developed to be more sporting. The Arnage R features two Garrett T3 turbochargers, as with the RL.The Arnage T, also from 2002, was claimed to be the most powerful roadgoing Bentley at its launch at the Detroit Motor Show. As with the Arnage R, there were twin-turbochargers, but tuned to develop 465 PS (459 bhp) and 645 lbf·ft. The Arnage T’s 0–60 mph time is 5.5 seconds; a top speed of 170 mph was claimed. The Arnage range was facelifted in 2005, with a front end resembling that of the new Continental GT. Production of the Arnage ceased in 2009.

From more recent production were examples of the Continental GT family.

BMW

The first example of the Z1 was released by BMW to the press in 1986 and later officially presented at the 1987 Frankfurt Motor Show. Initial demand was so fierce that BMW had 5,000 orders before production began. The Z1 was designed over a three-year period by an in-house division of BMW Forschung und Technik GmbH. The development of the Z1 is attributed to Ulrich Bez and his team at BMW Technik GmbH. The BMW Z1 was used to develop and debut several technologies. Z1 designer Harm Lagaay mentioned that Z1 production helped generate patents for BMW’s high-intensity discharge lamp, integrated roll-bar, door mechanism, and underbody tray. Both the engine and the five-speed manual transmission were sourced from the E30 325i. The 2.5 litre 12-valve SOHC straight-six engine sits tilted 20 degrees to the right to accommodate the low bonnet line. The engine produces 168 hp at 5,800 rpm and 164 lb·ft of torque in its original form. The rear suspension, called the Z Axle, was specially designed for the Z1 and this was one of the first BMWs to feature a multi-link design. In the 1990s, the Z Axle would be used on a variety of BMW Group vehicles, including the E36, 3 series, and the R40 Rover 75. The chassis was specially designed for the Z1 and featured a number of innovative features: removable body panels, continuously zinc welded seams, a composite undertray, and the unusual dropped doors. Parts of the car (including the engine, gearbox, and front suspension) were borrowed from the BMW E30 325i and 325Ix, but most of the Z1’s components are unique to the model, and that had the consequence of making it expensive. The body was made from plastic and could be removed completely from the chassis. The side panels and doors are made of General Electric’s XENOY thermoplastic. The hood, trunk, and roof cover are GRP components made by Seger + Hoffman AG. The car is painted in a special flexible lacquer finish developed jointly by AKZO Coatings and BMW Technik GmbH. During the Z1s launch, BMW suggested that owners purchase an additional set of body panels and change the colour of the car from time to time. The car could actually be driven with all of the panels completely removed, similar to the Pontiac Fiero. BMW noted that the body could be completely replaced in 40 minutes, although Z1 owners have reported that this may be optimistic. The entire vehicle was designed with aerodynamics in mind. Specifically, the entire undertray is completely flat and the exhaust and rear valance were designed as integral aerodynamic components to decrease turbulence and rear lift. The front end reportedly induces a high-pressure zone just forward of the front wheels to increase front-wheel traction. The Z1 has a drag coefficient of 0.36 Cd with the top up or 0.43 Cd with it down. The doors retract vertically down into the car’s body instead of swinging outward or upward. The Kaiser Darrin was the first car to have retractable doors; they slid forward into the front wings. The inspiration for these doors came from more traditional roadsters which often feature removable metal or cloth doors. Because removable doors did not fit within BMW’s design goals, the retractable doors were installed instead. The body with its high sills, offers crash protection independent of the doors, the vehicle may be legally and safely driven with the doors up or down, although this is not legal in the U.S. The windows may be operated independently of the doors, although they do retract automatically if the door is lowered. Both the window and door are driven by electric motors through toothed rubber belts and may be moved manually in an emergency. It took a while to get the Z1 into production, by which time demand had dropped considerably, perhaps due to reduced demand from speculators. In the end, BMW only produced 8,000 Z1 models. 6,443 of these were sold in BMW’s native German market. The country to receive the second-greatest number of Z1s, Italy, received less than 7% of the total sold domestically. BMW was reportedly unable to build more than 10 to 20 Z1 vehicles each day. None were initially sold in North America, although examples have been independently imported since the car’s launch. More than half of all Z1 vehicles (specifically, 4,091) were produced for the 1990 model year. Seventy-eight Z1 vehicles were reportedly used as test mules, although most were later sold without a warranty and, presumably, at a lower price. The Z1 was available in six exterior colours and four interior colours. Most (6,177) were red, black, or green with a dark grey interior. Light yellow exterior (fun-gelb in German or fun yellow in English, with 33 examples made and cars with a red interior (38 examples made) are the rarest Z1 colours. The colours swimming pool blue and oh-so-orange were reserved for the car’s designers, Bez and Lagaay. Reportedly, some 1,101 Z1 vehicles were delivered without a factory radio installed. In these vehicles, BMW AG installed an aftermarket Sony radio in its place. None of the Z1 vehicles were sold with air conditioning. The vehicle’s dashboard is very small and there was no room for both heat and cooling units. Some Z1 vehicles were converted using BMW E30 parts to have air conditioning, but reportedly the heater elements had to be removed. Although prices did drop from the new car cost of around £40,000, these have never been cheap cars to buy, and these days values are increasing again.

Also here were examples of the latest generation of the M2 and M3.

CHEVROLET

The Camaro was GM’s very definite response to the huge success of Ford’s Mustang, which had been codenamed Panther. Although there had been rumours that GM was doing something, this was an era when even the journalists were surprised. and on June 21, 1966, around 200 automotive journalists of them were when they received a telegram from General Motors stating, “…please save noon of June 28 for important SEPAW meeting. Hope you can be on hand to help scratch a cat. Details will follow…(signed) John L. Cutter – Chevrolet public relations – SEPAW secretary.” The following day, the same journalists received another General Motors telegram stating, “Society for the Eradication of Panthers from the Automotive World will hold first and last meeting on June 28…(signed) John L. Cutter – Chevrolet public relations SEPAW secretary.” These telegrams were something of a puzzle at the time. On June 28, 1966, General Motors held a live press conference in Detroit’s Statler-Hilton Hotel. It was to be the first time in history that 14 cities were connected in real time for a press conference via telephone lines. Chevrolet general manager Pete Estes started the news conference stating that all attendees of the conference were charter members of the Society for the Elimination of Panthers from the Automotive World and that this would be the first and last meeting of SEPAW. Estes then announced a new car line, project designation XP-836, with a name that Chevrolet chose in keeping with other car names beginning with the letter C such as the Corvair, Chevelle, Chevy II, and Corvette. He claimed the name, suggests the comradeship of good friends as a personal car should be to its owner and that to us, the name means just what we think the car will do… go. The Camaro name was then unveiled. Automotive press asked Chevrolet product managers, what is a Camaro? and were told it was a small, vicious animal that eats Mustangs. According to the book “The Complete Book of Camaro: Every Model Since 1967”, the name Camaro was conceived by Chevrolet merchandising manager Bob Lund and General Motors vice president Ed Rollett, while they were reading the book Heath’s French and English Dictionary by James Boïelle and by de V. Payen-Payne printed in 1936.  Lund and Rollett found the word “camaro” in the French-English dictionary to mean friend, pal, or comrade. The article further repeated Estes’s statement of what the word camaro was meant to imply, that the car’s name “suggests the comradeship of good friends, as a personal car should be to its owner”. In fact, the actual French word that has that meaning is “camarade”, from which the English word “comrade” is derived, and not “camaro”.  “Camaro” is not a recognised word in the French language. Be that as it may, the Camaro was first shown at a press preview in Detroit, Michigan, on September 12, 1966, and then later in Los Angeles, California, on September 19, 1966. Public introduction of the new model was on September 26, 1966. The Camaro officially went on sale in dealerships on September 29, 1966, for the 1967 model year It was an instant success. The first generation model ran for three years before an all new second generation car premiered (late) for the 1970 model year.

De TOMASO

Designed by American Tom Tjaarda, and unlike the Mangusta, which employed a steel backbone chassis, the Pantera was a steel monocoque design, the first instance of De Tomaso using this construction technique. The Pantera logo included a version of Argentina’s flag turned on its side with a T-shaped symbol that was the brand used by De Tomaso’s Argentinian cattle ranching ancestors. The car made its public debut in Modena in March 1970 and was presented at the 1970 New York Motor Show a few weeks later. Approximately a year later the first production Panteras were sold, and production was increased to three per day. The curious slat-backed seats which had attracted comment at the New York Show were replaced by more conventional body-hugging sports-car seats in the production cars: leg-room was generous but the pedals were off-set and headroom was insufficient for drivers above approximately 6 ft. Reflecting its makers’ transatlantic ambitions, the Pantera came with an abundance of standard features which appeared exotic in Europe, such as electric windows, air conditioning and even “doors that buzz when … open”. By the time the Pantera reached production, the interior was in most respects well sorted, although resting an arm on the central console could lead to inadvertently activating the poorly located cigarette lighter. The first 1971 Panteras were powered by a Ford 351 cu in (5.8 litre) V8 engine that produced a severely underrated 330 hp. Stock dynos over the years proved that power was more along the lines of about 380 hp. The high torque provided by the Ford engine reduced the need for excessive gear changing at low speeds: this made the car much less demanding to drive in urban conditions than many of the locally built competitor products. The ZF transaxle used in the Mangusta was also used for the Pantera: a passenger in an early Pantera recorded that the mechanical noises emanating from the transaxle were more intrusive than the well restrained engine noise. Power-assisted four-wheel disc brakes and rack and pinion steering were all standard equipment on the Pantera. The 1971 Pantera could accelerate to 60 mph in 5.5 seconds. In the summer of 1971, a visitor to the De Tomaso plant at Modena identified two different types of Pantera awaiting shipment, being respectively the European and American versions. From outside, the principal differences were the larger tail lamps on the cars destined for America, along with addition of corner marker lamps. The visitor was impressed by the large number of cars awaiting shipment; but in reality, spending the best part of a year under dust covers in a series of large hangars probably did nothing for the cash-flow of the business or the condition of some of the cars by the time they crossed the Atlantic. Late in 1971, Ford began importing Panteras for the American market to be sold through its Lincoln Mercury dealers. The first 75 cars were simply European imports and are known for their “push-button” door handles and hand-built Carrozzeria Vignale bodies. A total of 1,007 Panteras reached the United States that first year. These cars were poorly built, and several Panteras broke down during testing on Ford’s test track. Early crash testing at UCLA showed that safety cage engineering was not very well understood in the 1970s. Rust-proofing was minimal on these early cars, and the quality of fit and finish was poor, with large amounts of body solder being used to cover body panel flaws. Notably, Elvis Presley once fired a gun at his Pantera after it would not start. An L model (“Lusso”) was added in 1972 and a GTS version in 1974, but it was not enough and Ford ended their importation to the US in 1975, having sold around 5,500 cars. De Tomaso continued to build the car in ever-escalating forms of performance and luxury for almost two decades for sale in the rest of the world. A small number of Panteras were imported to the US by grey market importers in the 1980s, notably Panteramerica and AmeriSport. After 1974, Ford US discontinued the Cleveland 351 engine, but production continued in Australia until 1982. De Tomaso started sourcing their V8s from Australia once the American supplies dried up. These engines were tuned in Switzerland and were available with a range of outputs up to 360 PS. The chassis was completely revised in 1980, beginning with chassis number 9000. From May 1980 the lineup included the GT5, which had bonded and riveted-on fibreglass wheelarch extensions and from November 1984 the GT5S model which had blended arches and a distinctive wide-body look. The GT5 also incorporated better brakes, a more luxurious interior, much larger wheels and tires and the fibreglass body kit also included an air dam and side skirts. Production of the wide body GT5 (and similarly equipped narrow body GTS models) continued until 1985, when the GT5-S replaced the GT5. Although the factory has not made its records available, an analysis based on Vehicle Identification Numbers by the Pantera Owners Club of America (POCA) late model (9000 series) registrar has shown that fewer than 252 GT5 Panteras were likely to have been built. The GT5-S featured single piece flared steel fenders instead of the GT5’s riveted-on fibreglass flares, and a smaller steel front air dam. The ‘S’ in the GT5-S name stood for “steel”. Otherwise the GT5-S was largely identical to the GT5. The POCA 9000 series registrar’s VIN analysis indicates that fewer than 183 GT5-S Panteras were built. Concurrent GTS production continued, on a custom order and very limited basis, until the late 1980s. The car continued to use a Ford V8 engine, although in 1988, when the supply of Ford 351 Cleveland engines from Australia ran out, De Tomaso began installing Ford 351 Windsor engines in the Pantera instead. For 1990 the 351 was changed to the Ford 302 cu in (4942 cc, commonly called a “5.0”). Incorporating a Marcello Gandini facelift, suspension redesign, partial chassis redesign and the new, smaller engine, the Pantera 90 Si model was introduced in 1990. Only 38 90 Si models were sold before the Pantera was finally phased out in 1993 to make way for the radical, carbon-fibre-bodied Guarà. Some say 41 were built (with the last one not finished until 1996), of which four were targa models. The targas were converted by Pavesi directly off the production lines. In all, about 7,200 Panteras were built. The duo here were from the later production, with the much wider body and extended wheelarches.

DODGE

There was a very impressive showing of the modern day Challenger, all the more remarkable given the fact that the car has never officially been sold here.

FERRARI

The 330 GTC and 330 GTS were more like their 275 counterparts than the 330 GT 2+2. They shared the short wheelbase of the 275 as well as its independent rear suspension & the same tyres 205VR14 Michelin XWX. These models were more refined than earlier Ferraris, quieter and easier to drive. It has been stated that this “was probably the first Ferrari in which you could actually enjoy a radio”. The GTC berlinetta was introduced at the Geneva Motor Show in March, 1966. It was a two-seater coupé with a Pininfarina-designed body. A 1967 GTC was given one-off bodywork by Zagato at the behest of American importer Luigi Chinetti in 1974. This car was called the “Zagato Convertibile”, since it was of a targa-style. The GTS spider followed at the Paris Motor Show. About 600 coupés and 100 spiders were produced before the 1968 introduction of the 365 GTC and GTS. Both models’ four litre engines produced 300 PS 598 examples of the GTC were produced and 100 of the GTS.

Still seen by many as the most beautiful Ferrari ever built was the 246 GT Dino and this time there was just one example here. The Ferrari Dino was created to honour Alfredo ‘Dino’ Ferrari, Enzo Ferrari’s only legitimate son, who sadly died of muscular dystrophy in 1956. Unlike any previous road-going Ferrari, the Dino utilised a V6 engine, the Tipo 156, which Alfredo himself had helped develop and strongly advocated during his working life. Following continued motor racing success and in order to homologate Ferrari’s 1966 Formula Two campaign, a new line of mid-engined production V6 coupés with Fiat running gear went on sale in 1967 in two litre 206 GT form. However, in 1969 a larger 2.4 litre Dino was introduced, named the 246 GT or GTS in the case of the Spider. Only 3,913 definitive Dinos were built before the introduction of the completely restyled V8 engined 308 in 1973. The voluptuous bodywork of the 246, which many regard as the prettiest ever to grace a road-going Ferrari, was designed by Pininfarina and built by Scaglietti. It clothed a tubular chassis which carried wishbone independent suspension at each corner. The compact four-cam, 190bhp. engine was mounted transversely above the five-speed gearbox and just ahead of the rear axle, allowing for both a comfortable cockpit and some usable boot space.

The Dino 308 GT4 was introduced at the Paris Motor Show in 1973. It only gained the “Prancing Horse” badge in May 1976, which replaced the Dino badges on the front, wheels, rear panel and the steering wheel. This has caused major confusion over the years by owners, enthusiasts and judges. During the energy crisis at that time many prospective owners were hesitant to buy such an expensive automobile not badged “Ferrari” being confused at the significance of the Dino name. The GT4 was a groundbreaking model for Ferrari in several ways: it was the first production Ferrari to feature the mid-engined V8 layout that would become the bulk of the company’s business in the succeeding decades, and was the first production Ferrari with Bertone (rather than Pininfarina) designed bodywork. Pininfarina was upset by the decision to give cross-town rival Bertone the design, considering all they had done for Ferrari. The styling featured angular lines entirely different from its curvaceous 2-seater brother, the Dino 246, and was controversial at the time. Some journalists compared it to the Bertone-designed Lancia Stratos and Lamborghini Urraco, also penned by Marcello Gandini. From the cockpit the driver sees only the road. It has perfect 360 degree visibility, no blind spots, upright and comfortable seating position, a real boot, a back seat for soft luggage, and very easy engine access. Enzo Ferrari himself took a major role in its design, even having a mock-up made where he could sit in the car to test different steering, pedals and cockpit seating positioning. The chassis was a tubular spaceframe based on the Dino 246, but was stretched for a 115.2 in wheelbase to make room for the second row of seats. The suspension was fully independent, with double wishbones, anti-roll bars, coaxial telescopic shock absorbers and coil springs on both axles. Niki Lauda helped set up the chassis. The 2927 cc V8 was mounted transversally integrally joined with the 5-speed transaxle gearbox. The engine had an aluminium alloy block and heads, 16-valves and dual overhead camshafts driven by toothed belts; it produced 255 hp in the European version and 240 hp in the American. The induction system used four Weber 40 DCNF carburettors. The GT4 was replaced by the Mondial 8 in 1980 after a production run of 2,826 308s and 840 208s.

The 308 GTB was launched at the Paris Motor Show in 1975 as a direct replacement for the Dino 246. Designed by Pininfarina with sweeping curves and aggressive lines, the 308 has gone on to become one of the most recognised Ferraris of all time. Fitted with a 2.9 litre DOHC V8 engine fed by four Webber 40DCNF Carburettors, the power output of 255bhp was sufficient to propel the 308 from 0 to 60mph in 6.5 seconds and on to a top speed of 159 mph. Tougher emissions standards in the 1980s challenged Ferrari more than many other marques. In 1980, fuel injection was adopted for the first time on the 308 GTB and GTS models, and power dropped quite noticeably fro 240 bhp to 214bhp. Two years later, at the 1982 Paris Motor Show, Ferrari launched the 308 quattrovalvole, in GTB and GTS form. The main change from the 308 GTBi/GTSi it succeeded were the 4-valves per cylinder—hence its name, which pushed output back up to 240 hp restoring some of the performance lost to the emission control equipment. The new model could be recognised by the addition of a slim louvred panel in the front lid to aid radiator exhaust air exit, power operated mirrors carrying a small enamel Ferrari badge, a redesigned radiator grille with rectangular driving lights on each side, and rectangular (in place of round) side repeaters. The interior also received some minor updates, such as a satin black three spoke steering wheel with triangular centre; cloth seat centres became available as an option to the standard full leather. Available included metallic paint, a deep front spoiler, air conditioning, wider wheels, 16-inch Speedline wheels with Pirelli P7 tyres, and a satin black roof aerofoil (standard on Japanese market models). Apart from the 32-valve cylinder heads, the V8 engine was essentially of the same design as that used in the 308 GTSi model. The gear and final drive ratios were altered to suit the revised characteristics of the four valves per cylinder engine. One other significant benefit of the QV four valve heads was the replacement of the non-QV models sodium valves which have been known to fail at the joint between the head and the stem. Bosch K-Jetronic fuel injection and Marelli Digiplex electronic ignition were carried over from the GTBi/GTSi. The car was produced in this form until the launch of the 328 models in the autumn of 1985 which had larger 3.2 litre engines and a number of styling changes. 308 GTB models are becoming increasingly sought after, with prices rising steadily and quite steeply.

Introduced at the 1985 Frankfurt Show alongside the Mondial 3.2 series, the Ferrari 328 GTB and GTS (Type F106) were the successors to the Ferrari 308 GTB and GTS which had first been seen in October 1975. While mechanically still based on the 308 GTB and GTS respectively, small modifications were made to the body style and engine, most notably an increase in engine displacement to 3185 cc for increased power and torque output. As had been the case for a generation of the smaller Ferraris, the model name referred to the total cubic capacity of the engine, 3.2 litres, and 8 for the number of cylinders. Essentially the new model was a revised and updated version of the 308 GTS, which had survived for eight years without any radical change to the overall shape, albeit with various changes to the 3-litre engine. The 328 model presented a softening of the wedge profile of its predecessor, with a redesigned nose that had a more rounded shape, which was complemented by similar treatment to the tail valance panel. The revised nose and tail sections featured body colour bumpers integral with the valance panels, which reflected the work done concurrently to present the Mondial 3.2 models, with which they also shared a similar radiator grille and front light assembly layout. Thus all the eight-cylinder cars in the range shared fairly unified front and rear aspects, providing a homogeneous family image. The exhaust air louvres behind the retractable headlight pods on the 308 series disappeared, coupled with an increase in the size of the front lid radiator exhaust air louvre, which had been introduced on the 308 Quattrovalvole models, whilst a new style and position of exterior door catch was also provided. The interior trim also had a thorough overhaul, with new designs for the seat panel upholstery and stitching, revised door panels and pulls, together with more modern switchgear, which complemented the external updating details. Optional equipment available was air conditioning, metallic paint, Pirelli P7 tyres, a leather dashboard, leather headlining to the removable roof panel plus rear window surround, and a rear aerofoil (standard on Japanese market models). In the middle of 1988 ABS brakes were made available as an option, which necessitated a redesign of the suspension geometry to provide negative offset. This in turn meant that the road wheel design was changed to accommodate this feature. The original flat spoke “star” wheels became a convex design, in the style as fitted to the 3.2 Mondial models, whether ABS was fitted or not. The main European market 328 GTS models had a tubular chassis with a factory type reference F 106 MS 100. Disc brakes, with independent suspension via wishbones, coil springs, and hydraulic shock absorbers, were provided all round, with front and rear anti roll bars. There were various world market models, each having slight differences, with right and left hand drive available. The V8 engine was essentially of the same design as that used in the 308 Quattrovalvole model, with an increase in capacity to 3185 cc. The engine retained the Bosch K-Jetronic fuel injection system of its predecessor, but was fitted with a Marelli MED 806 A electronic ignition system, to produce a claimed power output of 270 bhp at 7000 rpm. As with the preceding 308 models the engine was mounted in unit with the all synchromesh five-speed manual transmission assembly, which was below, and to the rear of the engine’s sump. The 328 GTS continued in production for four years, until replaced by the 348 ts model in the autumn of 1989, during which time 6068 examples were produced, GTS production outnumbering the GTB (1344 produced) version almost five to one.

Produced alongside the 308/328 GTB and GTS models was the Mondial, and there were a couple of examples of the car on show. Produced by Ferrari from 1980 through 1993, it replaced the 208/308 GT4. The “Mondial” name came from Ferrari’s history — the 500 Mondial race car of the early 1950s. Despite its predecessor being Bertone styled, the Mondial saw Ferrari return to Pininfarina for styling. Sold as a mid-sized coupe and, eventually a cabriolet, it was conceived as a ‘usable’ model, offering the practicality of four seats and the performance of a Ferrari. The car had a slightly higher roofline than its stablemates, with a single long door either side, offering easy access and good interior space, reasonable rear legroom while all-round visibility was excellent. The cabriolets also hold the distinction of being the only production automobile in history that has four seats, is rear mid-engined, and is a full convertible. The car body was not built as a monocoque in the same way as a conventional car. The steel outer body produced by the famous Italian coachbuilder Carrozzeria Scaglietti, in nearby Modena, was built over a lightweight steel box-section space frame. The engine cover and rear luggage compartment lids are in light alloy. The seats and interior were trimmed in Connolly hide, contrasting with the body colour. Most cars were painted rosso red, but some were black or silver, and a few were dark blue. The Mondial was the first Ferrari car where the entire engine/gearbox/rear suspension assembly is on a detachable steel subframe. This design made engine removal for a major rebuild or cylinder head removal much easier than it was on previous models. Unusually, the handbrake is situated between the driver’s seat and the inner sill. Once the handbrake is set it drops down so as, not to impede egress and ingress. Instead of the conventional “H” shift pattern, the gearbox has 1st gear situated in a “dog leg” to the left and back, behind reverse. This pattern, otherwise known as a “reverse h-gate”, allows quicker gear shifts between 2nd and 3rd gear, and also between 4th and 5th. The Mondial underwent many updates throughout production. There were four distinct iterations (8, QV, 3.2, and t), with the latter 3 having two variations each. (coupe and cabriolet). The first car was introduced as the Mondial 8 at the 1980 Geneva Auto Salon. It was the first Ferrari to depart from the company’s simple 3-digit naming scheme, and some reviews found it relatively mild, compared to other Ferraris, regarding performance, drawing criticism from some in the motoring press. It used a mid/rear-mounted Bosch K-Jetronic fuel injection V8, shared with the 308 GTBi/GTSi, mounted transversely. The engine used in the 1973 Dino 308 GT4. The K-Jetronic system is mechanical, with a high-pressure pump which streams fuel continuously to the injectors; it does not have a computer, just a few relays to handle the cold start sequence etc. The chassis was also based on the 308 GT4, but with a 3.9 inch longer wheelbase at 104.3 in. The suspension was the classic layout of unequal-length double wishbones and Koni dampers all around. Today, the Mondial 8 is considered one of the marque’s most “practical” vehicles, due to its 214 hp, proven drivetrain, four seats, and relatively low cost of maintenance (major services can be performed without removing the entire engine/transmission subframe). 703 examples were made. The first Mondial engine, although a DOHC design, used just two valves per cylinder. The 1982 Quattrovalvole or QV introduced a new four-valve head; the combustion chamber design purportedly based on the early eighties Formula 1 engine. Again, the engine was shared with the contemporary 308 GTB/GTS QV, and produced a much more respectable 240 hp. Appearance was largely as per the Mondial 8, although with red engine heads and prominent “quattrovalvole” script at the rear. 1,145 coupés built between 1982 and 1985. A new Cabriolet body style added for 1983. Body styling remained the same as the coupé variant, with the roof maintaining the ‘buttress’ design of the roof, though the Cabriolet required the rear seats to be mounted closer together laterally. The introduction of the Cabriolet saw the popularity of the Mondial rise, particularly in the American market, where the convertible body style was highly desirable. The Cabriolet has the added distinction of being the only four-seat, mid-rear engine, convertible automobile ever manufactured in regular production. 629 units were produced between 1983 and 1985, making this the rarest version of the Mondial. Like the Ferrari 328, the Mondial’s engine grew in both bore and stroke to 3,185 cc in 1985. Output was now 270 PS. The Mondial 3.2 was first presented at the 1985 Frankfurt Auto Show in September that year. Available in both Coupé and Cabriolet forms, styling refreshed with restyled and body-coloured bumpers, similar to the 328 with more integrated indicators and driving lamps, and new alloy wheels with a more rounded face. The 3.2 also boasted a major interior update, with a more ergonomic layout and a more rounded instrument binnacle. Later cars, from 1987 onwards, also sported ABS brakes. Fuel injection remained the primarily mechanical Bosch K-Jetronic (CIS) with an O2 sensor in the exhaust providing feedback to a simple computer for mixture trimming via a pulse modulated frequency valve that regulated control fuel pressure. The ignition system was Marelli Microplex, with electronic advance control and one distributor per bank of the V8. The 1988 Mondial 3.2 would be the final model year that retained the relatively low maintenance costs of the 308/328 drivetrain, allowing major service items like timing belt and clutch replacement performed with the engine/transmission package still in the car. The final Mondial evolution was 1989’s Mondial t, which was a substantially changed model. It was visually different from preceding Mondial models, the most recognizable being the redesign of the air intakes to a smaller rectangular shape. Additionally, the door-handles were of a visually different design, as were the front and rear bumpers which became body coloured. New front and rear wings cover wider tracks and are re-profiled to a fuller shape compared to previous models, which feature a rolled lip. The ‘t’ called attention to the car’s new engine/transmission layout: the previously-transverse engine mounted longitudinally while the gearbox remained transverse, thus forming a ‘t’. By adopting this layout, a longer engine could be mounted lower in the chassis, improving handling dramatically. The ‘t’ configuration was used by Ferrari’s Formula One cars of the 1980s, and would be the standard for the marque’s future mid-engined V8 cars, beginning with the 348, introduced later in the year. The transverse manual gearbox fitted with a Limited Slip Differential with a twin-plate clutch design with bevel gears driving the wheels. Later in production, a Semi-automatic transmission termed “Valeo” was available as an option; while shifting was using a traditional gear lever, the clutch was actuated automatically without a clutch pedal. The engine was up to 3405 cc and 300 hp, controlled by Bosch Motronic DME 2.5 (later DME 2.7) electronic engine management that integrated EFI and ignition control into a single computer unit. Two of these used in the car: one for each bank of the engine. Engine lubrication upgraded to a dry-sump system. The Mondial’s chassis would underpin a new generation of 2-seat Ferraris, right up to the 360, but the 2+2 Mondial would end production just four and a half years later in 1993. However, the “t” layout of the engine and transaxle, adapted from Ferrari’s Formula One cars, continues to be used in mid-engined V8 model Ferraris to date, albeit with a more sophisticated chassis. The new layout saw the engine and transmission mounted on a removable subframe; the assembly removed from the underside of the vehicle for maintenance. This process is necessary for timing belt replacement, making this a costly procedure for the owner who does not have a lift. On the other hand, the clutch was now located at the very rear of the drive train. This arrangement makes clutch replacement and service a simple, inexpensive, and readily owner-do-able proposition. The “t” was home to other Ferrari firsts: It used power assisted steering for the first time and had a 3-position electronically controlled suspension for a variable trade-off between ride quality and road holding. It also had standard ABS. Total production of the t Coupe was 858 (45 Right Hand Drive), and the t Cabriolet of 1,017 (51 Right Hand Drive, meaning that around 6000 Mondial cars were produced over those 13 years, making it one of the most commercially significant Ferraris to date.

Object of many a poster on a young enthusiast’s bedroom wall when the car was new was the Testarossa and there was a couple of nice examples here. A replacement for the BB512i, the final iteration of Ferrari’s first ever mid-engined road car, the Testarossa was launched at the Paris Show in October 1984. The Pininfarina-designed car was produced until 1991, with the same basic design then going through two model revisions, with the 512 TR and later F512 M which were produced from 1992 to 1996 before the model was replaced by the front-engined 550 Maranello. Almost 10,000 Testarossas, 512 TRs, and F512 Ms were produced, making it one of the most-produced Ferrari models, despite its high price and exotic design. The Testarossa followed the same concept as the BB512, but was intended to fix some of the criticisms of the earlier car, such as a cabin that got increasingly hot from the indoor plumbing that ran between the front-mounted radiator and the midships-mounted engine and a lack of luggage space. This resulted in a car that was larger, and at 1,976 millimetres (78 in) wide the Testarossa was half a foot wider than the Boxer and immediately condemned for being too wide, though these days it does not appear anything like as wide as it did when new. This resulted in an increased wheelbase that stretched about 64 mm (2.5 in) to 2,550 mm (100 in) which was used to accommodate luggage in a carpeted storage space under the front forward-opening lid. The increase in length created extra storage space behind the seats in the cabin. Headroom was also increased with a roofline half an inch taller than the Boxer. The design came from Pininfarina with a team of designers led by design chief Leonardo Fioravanti, the designer of many contemporary Ferraris. The design was originated by Nicosia, but the guidance of Fioravanti was equally important. Being a trained aerodynamicist, Fioravanti applied his know-how to set the aerodynamics layout of the car. This meant the large side intakes were not only a statement of style but actually functional – they drew clean air to cool the side radiators and then went upward and left the car through the ventilation holes located at the engine lid and the tail. As a result, the Testarossa did not need a rear spoiler like Lamborghini’s Countach yet produced zero lift at its rear axle. The aerodynamic drag coefficient of 0.36 was also significantly better than the Lamborghini’s 0.42. Pininfarina’s body was a departure from the curvaceous boxer—one which caused some controversy. The side strakes sometimes referred to as “cheese graters” or “egg slicers,” that spanned from the doors to the rear wings were needed for rules in several countries outlawing large openings on cars. The Testarossa had twin radiators in the back with the engine instead of a single radiator up-front. In conjunction the strakes provided cool air to the rear-mounted side radiators, thus keeping the engine from overheating. The strakes also made the Testarossa wider at the rear than in the front, thus increasing stability and handling. One last unique addition to the new design was a single high mounted rear view mirror on the driver’s side. On US based cars, the mirror was lowered to a more normal placement in 1987 and quickly joined by a passenger side rear view mirror for the driver to be able to make safe easy lane changes. Like its predecessor, the Testarossa used double wishbone front and rear suspension systems. Ferrari improved traction by adding 10-inch-wide alloy rear wheels. The Testarossa drivetrain was also an evolution of the BB 512i. Its engine used near identical displacement and compression ratio, but unlike the BB 512i had four-valve cylinder heads that were finished in red. The capacity was 4,943 cc, in a flat-12 engine mid mounted. Each cylinder had four valves, lubricated via a dry sump system, and a compression ratio of 9.20:1. These combined to provide a maximum torque of 490 Nm (361 lb/ft) at 4500 rpm and a maximum power of 390 hp at 6300 rpm. That was enough to allow the Testarossa to accelerate from 0–60 mph in 5.2 seconds and on to 100 mph. The original Testarossa was re-engineered for 1992 and released as the 512 TR, at the Los Angeles Auto Show, effectively as a completely new car, with an improved weight distribution of 41% front: 59% rear. The F512 M was introduced at the 1994 Paris Auto Show, with the M standing for “modificata”. That car is easy to spot as it lost the pop-up headlights and gained awkward glazed in units.

The 1984 288 GTO was built to compete in the new Group B Race series and a minimum of 200 cars were required for homologation. However, after the death of Henri Toivonen and his co-driver Sergio Cresto in the 1986 Tour de Corse, the FIA disestablished the class, leaving just the Group A Rally championship. As a result, the GTO never raced and all 272 cars built remained purely road cars. Some of the GTO’s styling features were first displayed on a 308 GTB design exercise by Pininfarina shown at the 1977 Geneva Salon. The 288 GTO started out as a modified version of the 308/328 to hold down costs and to build the car quickly, but little of the 308/328 was left when the 288 GTO was finished. Easily noticeable differences were the GTOs bulging wing flares, larger front/rear spoilers, large “flag-style” outside mirrors and four driving lights at the far sides of the grille. Retained from the original 250 GTO were slanted air vents, put in the GTO’s rear wings to cool the brakes. The GTO also had wider body panels than the 308’s because they had to cover much larger Goodyear tyres mounted on racing wheels. The suspension’s height could be set higher for road use and lower for racing on tracks. Bodywork material was new and lighter for better acceleration and handing. The GTO’s weight was only 2,555 pounds, compared to 3,085-3,350 for the 308/328. Steel was used just for the doors because major body panels were made from moulded fibreglass. Kevlar was used for the engine cover, and the roof was made from Kevlar and carbon fibre. The “288” refers to the GTO’s 2.8 litre V8 engine as it used a de-bored (by 1 mm) V8 with twin IHI turbochargers, intercoolers, and Weber-Marelli fuel injection. The 2855 cc engine capacity was dictated by the FIA’s requirement for a Turbocharged engine’s capacity to be multiplied by 1.4. This gave the GTO a theoretical engine capacity of 3997 cc, just under the Group B limit of 4.0 litres. Unlike the 308’s 2926 cc engine, the GTO’s 2855 cc engine was mounted longitudinally, using the 308’s rear boot space. This was necessary to make room for the twin turbochargers and intercoolers. The racing transmission was mounted to the rear of the longitudinal engine, moving the rear differential and wheels aft. The arrangement also let the GTO use a more conventional race-car engine/transmission layout for such things as quick gear ratio changes for various tracks. As a result, the wheelbase was 110 mm (4.3 in) longer at 2,450 mm (96 in). The track was also widened to accommodate wider wheels and tyres to provide increased cornering and braking performance and the ability to apply 400 hp and 366 lb·ft of torque to the ground. The GTO was an impressive performer, with 0-60 mph times around 5 seconds. Ferrari claimed 0-125 mph (201 km/h) in 15 seconds flat and a top speed of 189 mph (304 km/h), making it the first street-legal production car to reach 300 km/h all 272 cars left the factory painted in Rosso Corsa, though a few have since been given a new look and colour. This is not actually a genuine GTO but rather a recreation, but it fools many people when they see it.

Launched in 1987, the F40 was the successor to the 288 GTO. It was designed to celebrate Ferrari’s 40th anniversary and was the last Ferrari automobile personally approved by Enzo Ferrari. At the time it was Ferrari’s fastest, most powerful, and most expensive car for sale. As soon as the 288 GTO was launched, Ferrari started the development of an evolution model, intended to compete against the Porsche 959 in FIA Group B. However, when the FIA brought an end to the Group B category for the 1986 season, Enzo Ferrari was left with five 288 GTO Evoluzione development cars, and no series in which to campaign them. Enzo’s desire to leave a legacy in his final supercar allowed the Evoluzione program to be further developed to produce a car exclusively for road use. In response to the quite simple, but very expensive car with relatively little out of the ordinary being called a “cynical money-making exercise” aimed at speculators, a figure from the Ferrari marketing department was quoted as saying “We wanted it to be very fast, sporting in the extreme and Spartan,” “Customers had been saying our cars were becoming too plush and comfortable.” “The F40 is for the most enthusiastic of our owners who want nothing but sheer performance. It isn’t a laboratory for the future, as the 959 is. It is not Star Wars. And it wasn’t created because Porsche built the 959. It would have happened anyway.” Power came from an enlarged, 2936 cc version of the GTO’s twin IHI turbocharged V8 developing 478 bhp. The F40 did without a catalytic converter until 1990 when US regulations made them a requirement for emissions control reasons. The flanking exhaust pipes guide exhaust gases from each bank of cylinders while the central pipe guides gases released from the wastegate of the turbochargers. Engines with catalytic converters bear F120D code. The suspension was similar to the GTO’s double wishbone setup, though many parts were upgraded and settings were changed; the unusually low ground clearance prompted Ferrari to include the ability to raise the vehicle’s ground clearance when necessary. The body was an entirely new design by Pininfarina featuring panels made of Kevlar, carbon fibre, and aluminium for strength and low weight, and intense aerodynamic testing was employed. Weight was further minimised through the use of a plastic windscreen and windows. The cars did have air conditioning, but had no sound system, door handles, glove box, leather trim, carpets, or door panels. The first 50 cars produced had sliding Lexan windows, while later cars were fitted with wind down windows. The F40 was designed with aerodynamics in mind. For speed the car relied more on its shape than its power. Frontal area was reduced, and airflow greatly smoothed, but stability rather than terminal velocity was a primary concern. So too was cooling as the forced induction engine generated a great deal of heat. In consequence, the car was somewhat like an open-wheel racing car with a body. It had a partial undertray to smooth airflow beneath the radiator, front section, and the cabin, and a second one with diffusers behind the motor, but the engine bay was not sealed. Nonetheless, the F40 had an impressively low Cd of 0.34 with lift controlled by its spoilers and wing. The factory never intended to race the F40, but the car saw competition as early as 1989 when it debuted in the Laguna Seca Raceway round of the IMSA, appearing in the GTO category, with a LM evolution model driven by Jean Alesi, finishing third to the two faster space-framed four wheel drive Audi 90 and beating a host of other factory backed spaceframe specials that dominated the races. Despite lack of factory backing, the car would soon have another successful season there under a host of guest drivers such as Jean-Pierre Jabouille, Jacques Laffite and Hurley Haywood taking a total of three second places and one third. It would later be a popular choice by privateers to compete in numerous domestic GT series. Although the original plan was to build just 400 cars, such was the demand that in the end, 1311 were built over a 4 year period.

With styling that had a close link to the Testarossa, the next V8 Ferrari to be launched, in 1989, was the 348, as a replacement for the 328 GTB/GTS models, and there were several examples of this model here. At launch, the 348 series were not that enthusiastically received by the press who found much to complain about. The 348’s styling differed from previous models with straked side air intakes and rectangular taillights resembling the Testarossa. Launched in two models, a coupe badged 348 tb (Trasversale Berlinetta) and targa roofed 348 ts (Targa), these were soon joined by a fully open car, the 348 Spider. All featured a normally aspirated 3.4-litre version of the quad-cam, four-valve-per-cylinder V8 engine. As with its predecessors, the model number was derived from this configuration, with the first two digits being the displacement and the third being the number of cylinders. The engine, which produced 300 hp was mounted longitudinally and coupled to a transverse manual gearbox, like the Mondial t with which the 348 shared many components. This was a significant change for Ferrari, with most previous small Ferraris using a transverse engine with longitudinal transmission. The “T” in the model name 348 tb and ts refers to the transverse position of the gearbox. The 348 was fitted with dual-computer engine management using twin Bosch Motronic ECUs, double-redundant anti-lock brakes, and self-diagnosing air conditioning and heating systems. Late versions (1993 and beyond) have Japanese-made starter motors and Nippondenso power generators to improve reliability, as well as the battery located within the front left fender for better weight distribution. Similar to the Testarossa but departing from the BB 512 and 308/328, the oil and coolant radiators were relocated from the nose to the sides, widening the waist of the car substantially, but making the cabin much easier to cool since hoses routing warm water no longer ran underneath the cabin as in the older front-radiator cars. This also had the side effect of making the doors very wide. The 348 was equipped with a dry-sump oil system to prevent oil starvation at high speeds and during hard cornering. The oil level can only be accurately checked on the dipstick when the motor is running due to this setup. The 348 was fitted with adjustable ride-height suspension and a removable rear sub-frame to speed up the removal of the engine for maintenance. Despite trenchant criticism of the car, especially its handling, 2,895 examples of the 348 tb and 4,230 of the 348 ts were produced.

Stung by the criticism of the 348, Ferrari undertook a comprehensive revision, creating the F355 model which they launched in May 1994. An evolution of the Ferrari 348, just about everything was changed, and improved. Design emphasis for the F355 was placed on significantly improved performance, but driveability across a wider range of speeds and in different environments such as low-speed city traffic was also addressed, as the Honda NS-X had proved that you could make a supercar that could be lived with every day. Apart from the displacement increase from 3.4 to 3.5 litres, the major difference between the V8 engine in the 348 and F355 was the introduction of a 5-valve cylinder head. This new head design allowed for better intake permeability and resulted in an engine that was considerably more powerful, producing 375 hp. The longitudinal 90° V8 engine was bored 2mm over the 348’s engine, resulting in the small increase in displacement. The F355 had a Motronic system controlling the electronic fuel injection and ignition systems, with a single spark plug per cylinder, resulting in an unusual 5 valves per cylinder configuration. This was reflected in the name, which did not follow the formula from the previous decades of engine capacity in litres followed by number of cylinders such as the 246 = 2.4 litres and 6 cylinders and the 308 of 3.0 litres and 8 cylinders. For the F355, Ferrari used engine capacity followed by the number of valves per cylinder (355 = 3.5 litres engine capacity and 5 valves per cylinder) to bring the performance advances introduced by a 5 valve per cylinder configuration into the forefront. 5. The frame was a steel monocoque with tubular steel rear sub-frame with front and rear suspensions using independent, unequal-length wishbones, coil springs over gas-filled telescopic shock absorbers with electronic control servos and anti-roll bars. The car allows selection between two damper settings, “Comfort” and “Sport”. Ferrari fitted all road-going F355 models with Pirelli tires, size 225/40ZR 18 in front and 265/40 ZR 18 in the rear. Although the F355 was equipped with power-assisted steering (intended to improve low-speed driveability relative to the outgoing 348), this could optionally be replaced with a manual steering rack setup by special order. Aerodynamic designs for the car included over 1,300 hours of wind tunnel analysis. The car incorporates a Nolder profile on the upper portion of the tail, and a fairing on the underbody that generates downforce when the car is at speed. These changes not only made the car faster but also much better to drive,m restoring Ferrari to the top of the tree among its rivals. At launch, two models were available: the coupe Berlinetta and the targa topped GTS, which was identical to the Berlinetta apart from the fact that the removable “targa-style” hard top roof could be stored behind the seats. The F355 would prove to be last in the series of mid-engined Ferraris with the Flying Buttress rear window, a lineage going back to the 1965 Dino 206 GT, unveiled at the Paris Auto Show. The Spider (convertible) version came later in the year. In 1997 the Formula One style paddle gear shift electrohydraulic manual transmission was introduced with the Ferrari 355 F1 adding £6,000 to the dealer asking price. This system promised faster gearchanges and allowed the driver to keep both hands on the steering wheel, It proved to be very popular and was the beginning of the end for the manual-transmission Ferrari. Ferrari produced 4,871 road-going Berlinetta models, of which 3,829 were 6-speed and 1,042 were F1 transmissions. The Spider proved to be the second-most popular F355 model, with a total production of 3,717 units, of which 2,664 were produced with the 6-speed transmission and another 1,053 produced with the F1 transmission. A total of 2,577 GTS models were produced, with 2,048 delivered with the 6-speed transmission and another 529 with the F1 transmission. This was the last GTS targa style model produced by Ferrari. This made a total production run of 11,273 units making the F355 the most-produced Ferrari at the time, though this sales record would be surpassed by the next generation 360 and later, the F430.

A front-engined grand tourer, the 456 was produced from 1992 until 2003, as an overdue replacement for the long-defunct front-engined 412 as the company’s V12 four seater.  Pietro Camardella and Lorenzo Ramaciotti at Pininfarina designed the original 456 which was available in GT and from 1996 in GTA forms. The difference in name signifies the transmission: the former has a six-speed manual and the latter has a four-speed automatic developed in partnership with FF Developments, in Livonia, MI (which was later purchased by Ricardo Engineering in the UK). This was only the fourth automatic transmission ever offered by Ferrari. The 5473 cc 65° V12 engine was derived from the Dino V6 rather than the more conventional 60° V12s used in the 412 and Daytona. It produced 442 PS with 4 valves per cylinder and Bosch Motronic M2.7 engine management. It could push the 1690 kg car and four passengers to 302 km/h (188 mph) making it the world’s fastest production four-seater. Acceleration to 100 km/h was just 5.2 seconds, with a 13.4 second quarter-mile time. At the time of its development it was the most powerful road car ever developed by Ferrari (aside from the F40). In 1996 engine was changed with Motronic M5.2 management and typed as F116C. The name 456, as was Ferrari practice, came from the fact that each cylinder displaces 456 cubic centimeters. This was the last Ferrari to use this naming convention. Despite its supercar performance, the 456 has a relatively unstressed engine, which has proven to be a very reliable unit. The chassis is a tubular steel spaceframe construction with a one-piece composite bonnet and body panels of aluminium. The body panels are welded to the chassis by using a special “sandwich filler” called feran that, when laid between, allows steel and aluminium to be welded. The Modificata 456M appeared in 1998, starting with chassis number 109589. Many changes were made to improve aerodynamics and cooling, and the interior – still featuring Connolly Leather – was freshened with new seats and other conveniences (fewer gauges on dash, and a new Becker stereo fitted in front of gear stick rather than behind as in the very shallow and special Sony head unit in the 456 GT). The 456 has a smaller grille with fog lights outside the grille, and lacked the bonnet-mounted air scoops. The undercarriage spoiler on the 456M is fixed, where the older 456 had a motorised spoiler that began its deployment above 105 km/h (65 mph). Power remained unchanged on the Modificata using Bosch Motronic M5.2 engine management at 442 PS; the cylinder firing order was changed for smoother running, and the torque remained the same for later versions of the 456 GT. The Tour de France Blue with Daytona Seats was the most desirable colour and leather combination. Approximately 3,289 of all versions were built, consisting of: 456 GT: 1,548; 456 GTA: 403; 456M GT: 688; 456M GTA: 650.

It was with the 360 Modena that sales of Ferrari models really took off, with unprecedented volumes of the car being sold. The 360 Modena was launched in 1999, named after the town of Modena, the birthplace of Enzo Ferrari. A major innovation in this all new model came from Ferrari’s partnership with Alcoa which resulted in an entirely new all-aluminium space-frame chassis that was 40% stiffer than the F355 which had utilised steel. The design was 28% lighter despite a 10% increase in overall dimensions. Along with a lightweight frame the new Pininfarina body styling deviated from traditions of the previous decade’s sharp angles and flip-up headlights. The new V8 engine, common to all versions, was of 3.6 litre capacity with a flat plane crankshaft, titanium connecting rods and generates 400 bhp Despite what looks like on paper modest gains in reality the power to weight ratio was significantly improved on over the F355, this was due to the combination of both a lighter car and more power. The 0 to 100 km/h acceleration performance improved from 4.6 to 4.3 seconds. The first model to be rolled out was the 360 Modena, available as a manual, or an F1 electrohydraulic manual. Next up was an open car. The 360 was designed with a Spider variant in mind; since removing the roof of a coupe reduces the torsional rigidity, the 360 was built for strength in other areas. Ferrari designers strengthened the sills, stiffened the front of the floorpan and redesigned the windscreen frame. The rear bulkhead had to be stiffened to cut out engine noise from the cabin. The convertible’s necessary dynamic rigidity is provided by additional side reinforcements and a cross brace in front of the engine. Passenger safety is ensured by a strengthened windscreen frame and roll bars. The 360 Spider displays a curvilinear waistline. The fairings imply the start of a roof, and stable roll bars are embedded in these elevations. Due to use of light aluminium construction throughout, the Spider weighs in only 60 kg heavier than the coupé. As with the Modena version, its 3.6 litre V8 with 400 bhp is on display under a glass cover. The engine — confined in space by the convertible’s top’s storage area — acquires additional air supply through especially large side grills. The intake manifolds were moved toward the center of the engine between the air supply conduits in the Spider engine compartment, as opposed to lying apart as with the Modena. In terms of performance, the 0-60 mph time was slightly slower at 4.4 seconds due to the slight weight increase, and the top speed was reduced from 189 to 180 mph. Despite the car’s mid-mounted V8 engine, the electrically operated top is able to stow into the compartment when not in use. The convertible top was available in black, blue, grey and beige. The transformation from a closed top to an open-air convertible is a two-stage folding-action that has been dubbed “a stunning 20 second mechanical symphony”. The interior of the Spider is identical to that of the coupé.

The 360 Challenge Stradale was a low production track day focused car based on the 360 Modena. From a handling and braking performance perspective was the equivalent of adding a FHP (Fiorano Handling Pack) to the 360, which was available for V12 models such as the 550, 575 or F599 but never separately for the V8’s. It was inspired by the 360 Modena Challenge racing car series so the focus was primarily on improving its track lapping performance credentials by concentrating on handling, braking and weight reduction characteristics, which are essential in pure racing cars. Ferrari engineers designed the car from the outset with a goal of 20% track day use in mind and 80% road use. With only a small 20 bhp improvement in engine power from the Modena (and boasting an improved power-to-weight ratio) the Challenge Stradale accelerates from 0 to 100 km/h (62 mph) in 4.1 seconds according to Ferrari, four tenths faster than a Modena, but bald figures do not paint the full picture. For the enthusiastic driver the differences are truly staggering; genuine systematic improvements were achieved to the setup and feel of the whole car. Throttle response from the digital throttle was ratcheted up and feedback through the steering wheel was enhanced. The responsiveness of the controls, the balance of the chassis, the braking performance and the driver feedback all contribute greatly to the overall driving experience. Thanks to CCM brakes borrowed from the Enzo, some lower weight parts and a FHP handling pack, the Challenge Stradale was able to claim an impressive 3.5 seconds improvement per lap of its Fiorano circuit compared to the Modena (the target was 2.5 seconds). In total, the Challenge Stradale is up to 110 kg (243 lb) lighter than the standard Modena if all the lightweight options are specified such as deleted radio, lexan (plexiglass) door window and Alcantara fabric (instead of the leather option). As much as 74 kilograms (207 lb) was taken off on the car by lightening the bumpers, stripping the interior of its sound deadening and carbon mirrors and making the optional Modena carbon seats standard. Resin Transfer Moulding was utilized for the bumpers and skirts, a carry over from the Challenge cars which resulted in lighter bumpers than on the Modena. The engine and transmission weight was slimmed down 11 kg (24 lb) through the use of a smaller, lighter weight sports (yet still stainless steel) exhaust back box and valved exit pipes. The Challenge Stradale also got Brembo carbon ceramic brakes as standard (which later became standard fitment on the F430) which shaved 16 kg off the curb weight and improved handling by reducing unsprung weight and completely eliminating brake fade. Cars fitted with the centre console stereo option, sub speaker box behind the seats and glass side windows re-gained approximately 30 kg over the best selected options (from a weight perspective). Challenge Stradale models are much sought after these days, and when they do come up for sale, they command a huge premium over the regular 360 Modena cars.

Firmly placed in Ferrari’s history as one of their finest big GTs, the 550 Maranello’s combination of stylish Pininfarina lines and front mounted 12-cylinder engine meant this car had the potential to become an instant classic, following in the footsteps of its forebear, the 365 GTB/4 ‘Daytona’, and if you look at the way the prices are steading to go, it’s clear that the potential is being realised. Launched in 1996, and with modern styling cues, a 5.5 litre V12 engine producing around 485bhp and a reported top speed of 199mph, the 550 Maranello was a serious motor car. A less frenetic power delivery, the six speed manual box and excellent weight distribution were all factors in the 550 becoming the perfect European Grand Tourer. Ferrari updated the car to create the 575M

There were several examples of the F430 here, of course, as this car sold in what were large quantities, by Ferrari standards. Effectively a mid-life update to the 360 Modena, the F430 debuted at the 2004 Paris Motor Show. Designed by Pininfarina, under the guidance of Frank Stephenson, the body styling of the F430 was revised from the 360 Modena, to improve its aerodynamic efficiency. Although the drag coefficient remained the same, downforce was greatly enhanced. Despite sharing the same basic Alcoa Aluminium chassis, roof line, doors and glass, the car looked significantly different from the 360. A great deal of Ferrari heritage was included in the exterior design. At the rear, the Enzo’s tail lights and interior vents were added. The car’s name was etched into the Testarossa-styled driver’s side mirror. The large oval openings in the front bumper are reminiscent of Ferrari racing models from the 60s, specifically the 156 “sharknose” Formula One car and 250 TR61 Le Mans cars of Phil Hill. Designed with soft-top-convertible. The F430 featured a 4.3 litre V8 petrol engine of the “Ferrari-Maserati” F136 family. This new power plant was a significant departure for Ferrari, as all previous Ferrari V8’s were descendants of the Dino racing program of the 1950s. This fifty-year development cycle came to an end with the entirely new unit. The engine’s output was 490 hp at 8500 rpm and 343 lb/ft of torque at 5250 rpm, 80% of which was available below 3500rpm. Despite a 20% increase in displacement, engine weight grew by only 4 kg and engine dimensions were decreased, for easier packaging. The connecting rods, pistons and crankshaft were all entirely new, while the four-valve cylinder head, valves and intake trumpets were copied directly from Formula 1 engines, for ideal volumetric efficiency. The F430 has a top speed in excess of 196 mph and could accelerate from 0 to 100 km/h in 3.9 seconds, 0.6 seconds quicker than the old model. The brakes on the F430 were designed in close cooperation with Brembo (who did the calipers and discs) and Bosch (who did the electronics package),resulting in a new cast-iron alloy for the discs. The new alloy includes molybdenum which has better heat dissipation performance. The F430 was also available with the optional Carbon fibre-reinforced Silicon Carbide (C/SiC) ceramic composite brake package. Ferrari claims the carbon ceramic brakes will not fade even after 300-360 laps at their test track. The F430 featured the E-Diff, a computer-controlled limited slip active differential which can vary the distribution of torque based on inputs such as steering angle and lateral acceleration. Other notable features include the first application of Ferrari’s manettino steering wheel-mounted control knob. Drivers can select from five different settings which modify the vehicle’s ESC system, “Skyhook” electronic suspension, transmission behaviour, throttle response, and E-Diff. The feature is similar to Land Rover’s “Terrain Response” system. The Ferrari F430 was also released with exclusive Goodyear Eagle F1 GSD3 EMT tyres, which have a V-shaped tread design, run-flat capability, and OneTRED technology. The F430 Spider, Ferrari’s 21st road going convertible, made its world premiere at the 2005 Geneva Motor Show. The car was designed by Pininfarina with aerodynamic simulation programs also used for Formula 1 cars. The roof panel automatically folds away inside a space above the engine bay. The conversion from a closed top to an open-air convertible is a two-stage folding-action. The interior of the Spider is identical to that of the coupé. Serving as the successor to the Challenge Stradale, the 430 Scuderia was unveiled by Michael Schumacher at the 2007 Frankfurt Auto Show. Aimed to compete with cars like the Porsche RS-models and the Lamborghini Gallardo Superleggera it was lighter by 100 kg/220 lb and more powerful (510 PS) than the standard F430. Increased power came from a revised intake, exhaust, and an ion-sensing knock-detection system that allows for a higher compression ratio. Thus the weight-to-power ratio was reduced from 2.96 kg/hp to 2.5 kg/hp. In addition to the weight saving measures, the Scuderia semi-automatic transmission gained improved “Superfast”, known as “Superfast2”, software for faster 60 millisecond shift-times. A new traction control system combined the F1-Trac traction and stability control with the E-Diff electronic differential. The Ferrari 430 Scuderia accelerates from 0-100 km/h in 3.6 seconds, with a top speed of 202 miles per hour. Ferrari claimed that around their test track, Fiorano Circuit, it matched the Ferrari Enzo, and the Ferrari F430’s successor, the Ferrari 458. To commemorate Ferrari’s 16th victory in the Formula 1 Constructor’s World Championship in 2008, Ferrari unveiled the Scuderia Spider 16M at World Finals in Mugello. It is effectively a convertible version of the 430 Scuderia. The engine produces 510 PS at 8500 rpm. The car has a dry weight of 1,340 kg, making it 80 kg lighter than the F430 Spider, at a curb weight of 1,440 kg (3,175 lb). The chassis was stiffened to cope with the extra performance available and the car featured many carbon fibre parts as standard. Specially lightened front and rear bumpers (compared to the 430 Scuderia) were a further sign of the efforts Ferrari was putting into this convertible track car for the road. Unique 5-spoke forged wheels were produced for the 16M’s launch and helped to considerably reduce unsprung weight with larger front brakes and callipers added for extra stopping power (also featured on 430 Scuderia). It accelerates from 0-100 km/h in 3.7 seconds, with a top speed of 315 km/h (196 mph). 499 vehicles were released beginning early 2009 and all were pre-sold to select clients.

Widely rumoured to be called the F60, Ferrari surprised everyone at its 2002 unveiling by giving it the name Enzo. This car was built using even more Formula One technology, such as a carbon-fibre body, F1-style electrohydraulic shift transmission, and carbon fibre-reinforced silicon carbide (C/SiC) ceramic composite disc brakes. Also used were technologies not allowed in F1 such as active aerodynamics and traction control. After a downforce of 7600 N (1700 lbf) is reached at 300 km/h (186 mph) the rear wing is actuated by computer to maintain that downforce. The Enzo’s F140 B V12 engine was the first of a new generation for Ferrari. It was based on the design of the V8 found in Maserati’s Quattroporte, using the same basic design and 104 mm (4.1 in) bore spacing. The Enzo formed the basis for a whole array of other very special cars, including the FXX and FXX Evoluzione cars and the Maserati MC12 and MC12 Evoluzione as well as the Ferrari P4/5 and the Millechilli. Originally, 349 of these were going to be produced, but Ferrari decided to add another 50 to the total, meaning 400 in total were produced up until 2004.

The next V12 engined Ferrari was the 599 GTB (internal code F141) a new flagship, replacing the 575M Maranello. Styled by Pininfarina under the direction of Ferrari’s Frank Stephenson, the 599 GTB debuted at the Geneva Motor Show in February 2006. It is named for its total engine displacement (5999 cc), Gran Turismo Berlinetta nature, and the Fiorano Circuit test track used by Ferrari. The Tipo F140 C 5999 cc V12 engine produced a maximum 620 PS (612 hp), making it the most powerful series production Ferrari road car of the time. At the time of its introduction, this was one of the few engines whose output exceeded 100 hp per litre of displacement without any sort of forced-induction mechanism such as supercharging or turbocharging. Its 448 ft·lb of torque was also a record for Ferrari’s GT cars. Most of the modifications to the engine were done to allow it to fit in the Fiorano’s engine bay (the original Enzo version could be taller as it would not block forward vision due to its mid-mounted position). A traditional 6-speed manual transmission as well as Ferrari’s 6-speed called “F1 SuperFast” was offered. The Fiorano also saw the debut of Ferrari’s new traction control system, F1-Trac. The vast majority of the 599 GTB’s were equipped with the semi-automatic gearbox, with just 30 examples produced with a manual gearbox of which 20 were destined for the United States and 10 remained in Europe. The car changed little during its 6 year production, though the range did gain additional versions, with the HGTE model being the first, with a number of chassis and suspension changes aimed at making the car even sharper to drive, and then the more potent 599GTO came in 2010. With 670 bhp, this was the fastest road-going Ferrari ever made. Just 599 were made. The model was superceded by the F12 Berlinetta in 2012. GTB and GTO versions were on show here.

The Ferrari 612 Scaglietti, a 2+2 coupé grand tourer, was produced between 2004 and 2010. The 612 Scaglietti was designed to replace the smaller 456 M; its larger size makes it a true 4 seater with adequate space in the rear seats for adults. The 612 was Ferrari’s second all-aluminium vehicle, the first being the 360 Modena. Its space frame, developed with Alcoa, was made from extrusions and castings of the material, and the aluminium body is welded on. The chassis of the 612 forms the basis of the later 599 GTB model. The 612 Scaglietti shared its engine with the Ferrari 575 Superamerica. The Scaglietti had a top speed of 320 km/h (198.8 mph) and a 0–100 km/h acceleration time of 4.2 seconds. It came with a either a 6-speed manual or the 6-speed F1A semi-automatic paddle shift system, a much refined version of the F1 system in the 360. The model was replaced by the Ferrari FF in 2011.

After a gap of some years, Ferrari added a 4 seater V8 model to the range at the 2008 Paris Motor Show, with the California. According to industry rumours, the California originally started as a concept for a new Maserati, but the resulting expense to produce the car led the Fiat Group to badge it as a Ferrari in order to justify the high cost of purchase; the company denies this, however. The California heralded a number of firsts for Ferrari: the first front engined Ferrari with a V8; te first to feature a 7-speed dual-clutch transmission; the first with a folding metal roof; the first with multi-link rear suspension; and the first with direct petrol injection. Bosch produced the direct injection system. The engine displaces 4,297 cc, and used direct injection. It delivered 453 bhp at 7,750 rpm; its maximum torque produced was 358 lbf·ft at 5,000 rpm. The resulting 106 bhp per litre of engine displacement is one of the highest for a naturally aspirated engine, as other manufacturers have used supercharging or turbocharging to reach similar power levels. Ferrari spent over 1,000 hours in the wind tunnel with a one-third-scale model of the California perfecting its aerodynamics. With the top up, the California has a drag coefficient of Cd=0.32, making it the most aerodynamic Ferrari ever made until the introduction of the Ferrari F12 Berlinetta. Throughout the California’s production, only 3 cars were built with manual transmission, including one order from the UK. On 15 February 2012, Ferrari announced an upgrade, which was lighter and more powerful. Changes include reducing body weight by 30 kg (66 lb), increased power by output of 30 PS and 11 lbf·ft, acceleration from 0–100 km/h (62 mph) time reduced to 3.8 seconds, introduction of Handling Speciale package and elimination of the manual transmission option. The car was released at the 2012 Geneva Motor Show as a 2012 model in Europe. To give the clients a more dynamic driving experience, an optional HS (Handling Speciale) package was developed as part of the update. It can be recognised by a silver coloured grille and ventilation blisters behind the front wheel wells. The HS package includes Delphi MagneRide magnetorheological dampers controlled by an ECU with 50% faster response time running patented Ferrari software, stiffer springs for more precise body control and a steering rack with a 9 per cent quicker steering ratio (2.3 turns lock to lock as opposed to the standard rack’s 2.5). A more substantive update came in 2014, with the launch of the California T, which remains in production. It featured new sheetmetal, a new interior, a revised chassis and a new turbocharged powertrain.

Next up was the 458, of which there were examples of both the closed Coupe and the later Spider model. An all new design, the 458 Italia was first officially unveiled at the 2009 Frankfurt Motor Show. Once more, Ferrari advised that the model incorporated technologies developed from the company’s experience in Formula 1. The body computer system was developed by Magneti Marelli Automotive Lighting. The 458 came with a 4,499 cc V8 engine of the “Ferrari/Maserati” F136 engine family, producing 570 PS ( 562 hp) at 9,000 rpm and 540 N·m (398 lb/ft) at 6,000 rpm with 80% torque available at 3,250 rpm. The engine featured direct fuel injection, a first for Ferrari mid-engine setups in its road cars. The only transmission available was a dual-clutch 7-speed Getrag gearbox, in a different state of tune shared with the Mercedes-Benz SLS AMG. There was no traditional manual option, making this the fourth road-car after the Enzo, Challenge Stradale and 430 Scuderia not to be offered with Ferrari’s classic gated manual. The car’s suspension featured double wishbones at the front and a multi-link setup at the rear, coupled with E-Diff and F1-Trac traction control systems, designed to improve the car’s cornering and longitudinal acceleration by 32% when compared with its predecessors. The brakes included a prefill function whereby the pistons in the calipers move the pads into contact with the discs on lift off to minimise delay in the brakes being applied. This combined with the ABS and standard Carbon Ceramic brakes caused a reduction in stopping distance from 100–0 km/h (62-0 mph) to 32.5 metres. Ferrari’s official 0–100 km/h (62 mph) acceleration time was quoted as 2.9–3.0 seconds with a top speed of 340 km/h (210 mph). In keeping with Ferrari tradition the body was designed by Pininfarina under the leadership of Donato Coco, the Ferrari design director. The interior design of Ferrari 458 Italia was designed by Bertrand Rapatel, a French automobile designer. The car’s exterior styling and features were designed for aerodynamic efficiency, producing a downforce of 140 kg (309 lb) at 200 km/h. In particular, the front grille features deformable winglets that lower at high speeds, in order to offer reduced drag. The car’s interior was designed using input from former Ferrari Formula 1 driver Michael Schumacher; in a layout common to racing cars, the new steering wheel incorporates many controls normally located on the dashboard or on stalks, such as turning signals or high beams. At launch the car was widely praised as being pretty much near perfect in every regard. It did lack a fresh air version, though, but that was addressed with the launch of the 458 Spider at the 2011 Frankfurt Motor Show. This convertible variant of the 458 Italia featured an aluminium retractable hardtop which, according to Ferrari, weighs 25 kilograms (55 lb) less than a soft roof such as the one found on the Ferrari F430 Spider, and can be opened in 14 seconds The engine cover was redesigned to accommodate the retractable roof system. It had the same 0–100 km/h time as the hard-top but a lower top speed of 199 mph. It quickly became the better seller of the two versions.

Also here were examples of the 458 Speciale, and the open=topped Speciale A, the latest of a long line of specially engineered cars added to complement the “regular” V8 models that started  with the 100 units of the 348 Speciale produced in 1992, and followed up by the 360 Challenge Stradale, the 430 Scuderia and the 16M. In essence they are all about adding power and shedding weight. In simplistic terms, the road to the Speciale can be summed up in four words: more power, less weight. There are other, more detailed changes, too, obviously, but those are the cornerstones around which everything else is shaped. The normally aspirated, flat-plane crank V8 retains its 4497cc swept capacity but receives new cam geometry with higher valve lift, shorter inlet manifolds and different pistons providing a higher compression ratio. Internal friction is reduced, through the use of uprated materials and the upshot is 597bhp (up from 562bhp) generated at the engine’s 9000rpm limit. Torque is the same, at 398lb ft, still delivered at 6000rpm. The engine is mated to a seven-speed, dual-clutch gearbox whose upshifts, we were told at the launch of such gearboxes, are all but instant. That’s still true, but Ferrari has improved the response time to a pull on the lever and made the engine rev-match more quickly on downshifts to reduce the time that those take. The engine’s changes shave 8kg from the car’s overall weight – the exhaust is all aluminium and the intake is carbonfibre. Those 8kg form part of a claimed 90kg total saving at 1395kg now, versus 1485kg for a 458 Italia. Of this 90kg, 12kg is contributed by lighter, forged wheels, 13kg comes from bodywork and window changes (lighter glass all round and Lexan for the engine cover), and 20kg comes from the cabin. There are two flaps on the Speciale’s front valance, one either side of the prancing horse badge in its centre. Below 106mph these flaps remain closed, which diverts air towards the radiators. Above that speed, the radiators get quite enough cool air, thanks very much, so the flaps open, which reduces drag. Then, above 137mph, they move again, lowering to shift downforce to the rear of the car, in turn adjusting the balance 20 per cent rearward in order to promote high-speed cornering stability.  At the rear, meanwhile, there is a new diffuser (the exhausts have been rerouted to make the most of its central section). Movable flaps in the diffuser adjust, but this time they are dependent not only on speed but also on steering angle and throttle or brake position. When lowered, the flaps stall the path of air into the diffuser and improve the Cd by 0.03. When raised, the diffuser adds downforce as it should. Bodywork changes, though, also bring some aerodynamic improvements, you’ll not be surprised to hear, with lessons applied from the LaFerrari and FXX programmes. In the front valance and under the rear diffuser, there are flaps that open at speed to reduce drag and improve downforce. Finally, there are new Michelin Pilot Sport Cup 2 tyres in a unique compound – rather a sticky one, we suspect – plus new calibration for the adaptive dampers. The carbon-ceramic brake discs also use a new compound.  499 of them were built and they sold out very quickly.

The Ferrari FF (FF meaning “Ferrari Four”, for four seats and four-wheel drive, the Type F151) is a grand tourer presented by Ferrari on March 1, 2011 at the Geneva Motor Show as a successor to the 612 Scaglietti and is Ferrari’s first production four-wheel drive model. The body style has been described as a shooting-brake, a type of sporting hatchback/estate car with two doors. With a top speed of f 335 km/h (208 mph) and it accelerates from 0 to 100 km/h (62 mph) in 3.7 seconds, Ferrari stated that the FF was the world’s fastest four-seat automobile upon its release to the public. At the time of its reveal, the Ferrari FF had the largest road-going Ferrari engine ever produced: an F140 EB 6,262 cc naturally aspirated direct injected 65° V12, which produced 660 PS (485 kW; 651 hp) at 8,000 rpm and 683 N⋅m (504 lb⋅ft) of torque at 6000 rpm. The FF is equipped with a 7-speed dual-clutch transmission and paddle shift system similar to the California, the 458 Italia, and the Ferrari F12berlinetta. The new four-wheel drive system, engineered and patented by Ferrari, is called 4RM: it is around 50% lighter than a conventional system, and provides power intelligently to each of the four wheels as needed. It functions only when the manettino dial on the steering wheel is in the “comfort” or “snow” positions, leaving the car most often in the traditional rear wheel drive layout. Ferrari’s first use of 4RM was in a prototype created in the end of the 80s, called 408 4RM (abbreviation of “4.0 litre, 8 cylinder, 4 Ruote Motrici”, meaning “four-wheel drive”). This system is based around a second, simple, gearbox (gears and other components built by Carraro Engineering), taking power from the front of the engine. This gearbox (designated “power take off unit”, or PTU) has only two forward gears (2nd and 4th) plus reverse (with gear ratios 6% taller than the corresponding ratios in the main gearbox), so the system is only active in 1st to 4th gears. The connection between this gearbox and each front wheel is via independent Haldex-type clutches, without a differential. Due to the difference in ratios “the clutches continually slip” and only transmit, at most, 20% of the engine’s torque. A detailed description of the system (based on a conversation with Roberto Fedeli, Ferrari’s technical director) has been published. The FF shares the design language of contemporary Ferraris, including the pulled-back headlights of the 458 Italia, and the twin circular taillights seen on the 458 as well as the 599 GTB Fiorano. Designed under the direction of Lowie Vermeersch, former Design Director at Pininfarina, and Flavio Manzoni, Ferrari’s Styling Centre, work on the shooting brake concept initially started following the creation of the Sintesi show car of 2007. Distinctive styling elements inclubde a large egg-crate grille, defined side skirts, and four exhaust tips. The shooting brake configuration is a departure from the conventional wedge shape of modern Ferraris, and the FF has been likened to the similarly-shaped 1962 Ferrari 250 GT SWB Drogo race car. The combination of hatchback-like shooting-brake design and collapsible rear seats gives the Ferrari FF a boot capacity of between 16 and 28 cu ft. Luxury is the main element of the interior and the use of Leather is incorporated throughout, just like the predecessors of the FF. Creature comforts like premium air conditioning, GPS navigation system, carpeting and sound system are also used. An updated version. called the GTC4 Lusso was launched in 2016 by which 2291 examples had been built.

The Ferrari F12berlinetta (Type F152) is a front mid-engine, rear-wheel-drive grand tourer which debuted at the 2012 Geneva Motor Show, and replaces the 599 grand tourer. The naturally aspirated 6.3 litre Ferrari V12 engine used in the F12berlinetta has won the 2013 International Engine of the Year Award in the Best Performance category and Best Engine above 4.0 litres. The F12berlinetta was named “The Supercar of the Year 2012” by car magazine Top Gear. The F12berlinetta was replaced by the 812 Superfast in 2017.

The F12 TdF was unveiled in October 2015, as a faster, lighter and more powerful special edition of the regular F12 Berlinetta. The accompanying press releases informed us that the the car was created in homage to the legendary Tour de France road races, which it dominated in the 1950s and 1960s with the likes of the 1956 250 GT Berlinetta. However, the full Tour de France name cannot be used, as this is registered to the famous annual cycle race held in France, and even the might of Ferrari’s often belligerent and bullying legal department clearly had not managed to get past that obstacle. The F12 TdF,  described by its maker as “the ultimate expression of the concept of an extreme road car that is equally at home on the track”, keeps the same 6.3-litre naturally aspirated V12 engine as the regular F12 Berlinetta, but power has been boosted from 730bhp to 770bhp at 8500rpm, while torque has increased from 509lb ft to 520lb ft at 6750rpm. Ferrari says 80% of the car’s torque is available from 2500rpm. By comparison, McLaren’s 675LT features a 3.8-litre twin-turbocharged V8 engine and produces 660bhp and 516lb ft – enough to give it a 0-62mph sprint time of 2.9 seconds. The older Ferrari 458 Speciale, meanwhile, made 597bhp from its 4.5-litre naturally aspirated V8. The car  is capable of reaching 62mph in 2.9sec and has a top speed of more than 211mph. Official fuel consumption is rated at 18.3mpg, with CO2 emissions of 360g/km. Ferrari says it has has used various modifications derived from its F1 cars to boost the engine’s efficiency. The F12 TdF uses a new version of the firm’s dual-clutch automatic transmission, which features shorter gear ratios. New one-piece brake calipers – the same as those used on the LaFerrari supercar – are said to provide “outstanding” stopping distances, allowing the F12 TdF to brake from 62-0mph in 30.5 metres. Ferrari says the car’s performance is “second to none”, but that it has also been conceived to be “an extremely agile and powerful car which could also be driven by less expert drivers”. The F12 TdF  has lapped Ferrari’s Fiorano test track in 1min 21sec. The regular F12 Berlinetta completed the lap in 1min 23sec – the same as the new 488. The LaFerrari currently holds the fastest time on the course, with a time of 1min 19.70sec. Among the other changes made to the F12 TdF are larger front tyres, allowing greater lateral acceleration through corners. Ferrari says the car’s “natural tendency” to oversteer has been compensated for by the use of a new rear-wheel steering system. Dubbed Virtual Short Wheelbase, the system – which automatically adjusts the rear wheels for the optimum steering angle – is said to increase stability at high speeds while guaranteeing “the steering wheel response times and turn-in of a competition car”. The F12 TdF’s aggressive bodywork includes a longer and higher rear spoiler, larger air vents to channel air flow along the sides of the car, a redesigned rear diffuser and new wheel arch louvres. It sits on 20in alloy wheels. Overall, the changes combine to give the F12 TdF 30% more downforce compared to the F12. Ferrari says the redesigned bodywork has almost doubled the aerodynamic efficiency of the car compared to the standard F12, while the use of lightweight carbonfibre inside and out has reduced the F12 TdFf’s kerb weight by 110kg over the standard car, which weighs 1630kg. The cabin is deliberately stripped out. The door panels feature carbonfibre trim, while knee padding replaces the traditional glovebox. The majority of the cabin is trimmed with Alcantara instead of real leather. Aluminium plates feature on the floor instead of mats, again hinting at the car’s track-focused nature. Just 799 examples were built, around 20 of which came to the UK, with an  asking price of  £339,000, around £100,000 more than the regular F12 Berlinetta.

The Ferrari California T (Type 149M) is an updated design of the California model featuring new sheetmetal and revised body features; a new interior, a revised chassis and a new turbocharged powertrain. First unveiled on the web on February 12, 2014, subsequently, the car debuted at the Geneva Motor Show. The T in the moniker stands for Turbo, a technology Ferrari last used on the F40 roadcar. The car utilizes a new 3,855 cc twin-turbocharged V8 engine that produces 560 PS (553 bhp) at 7,500 rpm and 755 Nm (557 lb/ft) at 4,750 rpm as well as a 7-speed dual clutch transmission with different gear ratios, a revised MagneRide adaptive suspension, as well as a new F1 Trac system. The car can accelerate from 0–100 km/h (0–62 mph) in 3.6 seconds and attain a top speed of 315 km/h (196 mph). The car also features a new front fascia that was influenced by the F12, a revised rear section and a revised interior. The revised rear end replaced the two sets of two vertically stacked exhaust pipes with four horizontally aligned pipes. Another improvement to the car is the reduction of emission pollution by 15% compared to its naturally aspirated predecessor. The car also utilises small turbo chargers and a variable boost management system to reduce turbo lag. It is also the first Ferrari road car debuting the new Apple CarPlay functionality into its built-in infotainment system – Apple confirmed at the launch of the Geneva Motor Show that Ferrari, Mercedes-Benz and Volvo would be among the first car manufacturers to bring CarPlay compatible models to the market. Similarly to the previous generation, a Handling Speciale (HS) package was made available for the California T, providing sportier handling at the expense of a stiffer ride. The Handling Speciale includes stiffer springs front and aft, retuned magnetorheological dampers, faster gear shifts when in Sport mode, a reprogrammed F1-Trac stability control, and a new sport exhaust system. Visually, the HS package-equipped cars are distinguished by a matte grey grille and rear diffuser, matte black diffuser fences and matte black exhaust tips. The California T Handling Speciale was unveiled at the March 2016 Geneva Motor Show. Through the Tailor Made programme, the California T was produced in several special editions and could also be customised to suit individual customers. For Ferrari’s 70th anniversary in 2017, this included 70 liveries inspired by the company’s iconic cars of the past such as the 250 GT Berlinetta SWB and Steve McQueen’s 1963 250 GT Berlinetta lusso. The California T Tailor Made liveries were unveiled at the March 2016 Geneva Motor Show and also shown at other subsequent motor shows such as the October 2016 Paris Motor Show. Production ceased in 2019 when the car was replaced by the Portofino.

Also here was the Ferrari 812 Superfast. Known internally as the Type F152M, this is a front mid-engine, rear-wheel-drive grand tourer that made its debut at the 2017 Geneva Motor Show. The 812 Superfast is the successor to the F12berlinetta. The 812 Superfast has a 6,496 cc F140 GA V12, an enlarged version of the 6.3-litre engine used in the F12berlinetta. It generates a power output of 800 PS (789 bhp) at 8,500 rpm and 718 Nm (530 lb/ft) of torque at 7,000 rpm. According to Ferrari in 2018, the 812 Superfast’s engine was, at the time, the most powerful naturally aspirated production car engine ever made. It does not feature turbocharging or hybrid technology.

The GTC4Lusso is a successor to the Ferrari FF. Like its predecessor, the GTC4Lusso is a 3-door shooting-brake with an all-wheel drive drivetrain, and is powered by a front-mid mounted V12 engine. The GTC4Lusso’s 6,262 cc Ferrari F140 65° V12 engine is rated at 690 PS at 8,000 rpm and 697 Nm (514 lb/ft) of torque at 5,750rpm. The increase in output of the engine is due to the compression ratio raised to 13.5:1. Ferrari claims a top speed of 335 km/h (208 mph), unchanged from the FF, and a 0–100 km/h (0–62 mph) acceleration time of 3.4 seconds. The car uses an improved version (called the 4RM Evo) of Ferrari’s patented four-wheel drive system introduced on the FF, integrated with four-wheel steering into the system. Collectively, the system is called 4RM-S. The GTC4Lusso was unveiled at the 2016 Geneva Motor Show. A second version joined the range, unveiled at the 2016 Paris Motor Show. This was the GTC4Lusso T, a rear wheel drive only version of the GTC4Lusso powered by a V8 engine with lesser displacement, though the 4WS four-wheel steering system from its V12 variant is retained. The GTC4Lusso T comes with a 3,855 cc Ferrari F154 twin turbocharged V8 engine rated at 610 PS at 7,500 rpm and 760 Nm (561lb/ft) of torque at 3,000–5,250 rpm. According to the manufacturer the car can attain a top speed of over 320 km/h (199 mph) and accelerate from 0 to 100 km/h (0 to 62 mph) in 3.5 seconds. The rear features Ferrari’s signature Quad Circular Rear Lights (last seen on the F430) and the interior contains a Dual Cockpit Concept Design, separating the Driver Cockpit and the Passenger Cockpit by a central divider. The front of the car has a single grille that provides all the necessary cooling.

The Ferrari Portofino (Type F164) is a grand touring sports car. It is a two-door 2+2 hard top convertible, with a 3.9 L twin-turbo V8 engine and a 0–60 mph time of 3.5 seconds.  The car is named after the village of Portofino on the “Italian Riviera” and succeeds the company’s previous V8 grand tourer, the California T. The car was unveiled at the 2017 Frankfurt Motor Show. The 2020 Ferrari Roma coupe is based on the Portofino. A convertible version of the Roma was unveiled in 2023 to replace the Portofino. The Ferrari Portofino was unveiled on the Italian Riviera in the village of Portofino at two exclusive evenings on 7 and 8 September 2017, at which Piero Ferrari, Sergio Marchionne, Sebastian Vettel, and Giancarlo Fisichella were present. It was also shown at Maranello on September 9 and 10 during the Ferrari 70th Anniversary celebration. By the end of 2017, the Portofino was unveiled in Asia, namely China and Japan, where China is said to be a big market for the car. In Japan, the vehicle was initially private-previewed in November, before its official debut in February 2018. Prices in Japan start from JPY25,300,000. Prices in the U.S. start from $215,000. In Hong Kong, the Portofino was launched in late March 2018, making it the third time in Ferrari’s history to launch a new car in the Hong Kong’s Peninsula Hotel (Enzo in 2003, followed by FF in 2010). Unlike previous occasions where the vehicle launch occurred in only one part of the ground floor lobby, the Portofino’s launch occupied the hotel’s entire ground floor area, where a few other Ferrari models were also parked outside the drop-off area, and creative lighting featuring the Ferrari’s Prancing Horse logo was also projected on the hotel’s exterior walls. A China-spec, left-hand drive model was displayed, which features a simplified Chinese menu display—a rare move for Ferrari as not all Chinese-speaking Asian regions would receive a Chinese language menu. Pricing for the Portofino in Hong Kong (as of April 2018) starts from HK$3.5M, with deliveries scheduled later in the year. A right-hand drive model was first spotted at the city’s 488 Pista launch event in late June 2018. The chassis of the Portofino is made of 12 different aluminium alloys with much of its components now being integrated. The A-pillar of its predecessor consisted of 21 separate components but it is now a single piece in the Portofino. Hollow castings allow for increased structural rigidity, increasing it by 35% over its predecessor, the Ferrari California T. Its body has drag coefficient of Cd=0.312. Weight saving has been kept in focus while the development of the Portofino was carried out. Ferrari engineers managed to shave weight from the powertrain, dashboard structure, air-conditioning and heating and electronic systems of the car resulting in a weight of 1,664 kg (3,668 lb), making the car 80 kg (176 lb) lighter than its predecessor. The engine, a 3,855 cc Ferrari F154BE twin-turbocharged V8, is the same as in the Ferrari GTC4Lusso T, but yields a slightly de-tuned power output of 592 bhp (600 PS) at 7,500 rpm and 760 Nm (561 lb/ft) of torque at 3,000 to 5,250 rpm. Changes to the engine include a 10% pressure increase in the combustion chamber, revised connecting rods and pistons and a single cast exhaust manifold. The car retains the 7-speed dual clutch transmission from its predecessor but features a new software to allow for faster gear shifts. The exhaust system has been tweaked to give the car a proper sound note while maintaining its grand touring nature, featuring an adjustable electric bypass valve that monitors the engine’s sound according to driving conditions. The Portofino can accelerate from 0–100 km/h (0–62 mph) in 3.5 seconds, 0–200 km/h (0–124 mph) in 10.8 seconds and can attain a top speed of 320 km/h (199 mph). The Portofino features optional magnetorheological dampers, a carryover from the California, with an improved software to maintain good ride quality even though having a stiffer suspension system than the California. Like the company’s V12 grand tourer 812 Superfast, the Portofino features an electrically assisted power steering. Both the suspension system and steering become increasingly responsive when the car is in sports mode. The interior of the Portofino was developed after taking input from various clients. The rear seats have increased legroom (by 5 cm) and the infotainment system is more advanced and easier to use, featuring a 10.2-inch display screen in the centre console with optional Apple CarPlay functionality, as in its predecessor. The air conditioning system has been refined as well and is now 25% faster and 50% quieter than the California’s. On 16 September 2020, Ferrari launched the Portofino M (Modificata or Modified). The power was increased to 612 bhp (620 PS) and was released in the middle of 2021.

Launched at the 2015 Geneva Show, the 488GTB followed the lead set by the California T in bringing turbocharging into a modern-day, mid-engined V8 Ferrari supercar for the first time. The engine is completely new when compared with its V8 stablemate, not only in components but also in feel and character. It is a twin-turbocharged 3902cc unit whilst that in the California T is 3855cc. In the 488 GTB, it produces 660bhp at 8000rpm and 560lb ft at 3000rpm. Both outputs are significant increases over the normally aspirated 4.5-litre V8 used in the 562 bhp 458 Italia and 597 bhp 458 Speciale, and also greater than the car’s biggest rival, the McLaren 650S. The torque figure of the 488 GTB is such that it also exceeds the 509lb ft at 6000rpm of the normally aspirated V12 used in the range-topping Ferrari F12 Berlinetta. The mighty new engine in the 488 GTB drives the rear wheels through a revised seven-speed dual-clutch automatic gearbox derived from the 458. It features a new ‘Variable Torque Management’ system which, Ferrari says, “unleashes the engine’s massive torque smoothly and powerfully right across the rev range”. The gear ratios are also tuned to “deliver incredibly progressive acceleration when the driver floors the throttle”. The 488 GTB can crack 0-62mph in just 3.0sec, 0-124mph in 8.4sec and reach a top speed of 205mph. Its 0-62mph and 0-124mph times match the McLaren 650S’s, but the Woking car’s top speed is slightly higher at 207mph. The engine also accounts for the ‘488’ element of the car’s name, because each of the engine’s eight cylinders is 488cc in capacity when rounded up. The GTB suffix, standing for Gran Turismo Berlinetta, is a hallmark of previous mid-engined V8 Ferraris such as the 308 GTB. Not only is the new turbo engine more potent than the 4.5-litre V8 from the 458 Italia, but it is also more economical. Combined fuel economy is rated at 24.8mpg, compared with 21.2mpg in the 458 Italia, and CO2 emissions are 260g/km – a 47g/km improvement. Ferrari’s HELE engine stop-start system features on the 488 GTB. Developments on the dynamic side include a second generation of the Side Slip Angle Control system, called SSC2. This allows the driver to oversteer without intruding, unless it detects a loss of control. The SSC2 now controls the active dampers, in addition to the F1-Trac traction control system and E-Diff electronic differential. Ferrari says the result is “more precise and less invasive, providing greater longitudinal acceleration out of corners” and flatter, more stable behaviour during “complex manoeuvres”. Learnings from the Ferrari XX programme have also been incorporated into the 488 GTB, something that Ferrari says allows all drivers and not just professionals, to make the most of its electronic and vehicle control systems. It also claims the 488 GTB is “the most responsive production model there is”, with responses comparable to a track car. The 488 GTB has lapped Ferrari’s Fiorano test track in 1min 23sec – two seconds faster than the 458 Italia, and half a second quicker than the 458 Speciale. The dimensions of the 488 GTB – it is 4568mm in length, 1952mm in width and 1213mm in height – closely match the 458 Italia from which it has evolved. Its dry weight is 1370kg when equipped with lightweight options – 40kg more than the McLaren 650S. The new look, styled at the Ferrari Styling Centre, features several new aerodynamic features that improve downforce and reduce drag. Most notable is the addition of active aerodynamics at the rear through a ‘blown’ rear spoiler, where air is channelled from the base of the glass engine cover under the spoiler. This contributes to the 50% increase in downforce over the 458 Italia. Also new is a double front spoiler, an aerodynamic underbody, a large air intake at the front that references the 308 GTB, a diffuser with active flaps, new positioning for the exhaust flaps and new-look lights. The interior has been redesigned to be made more usable, including new switchgear, air vents and instrument panel. The multi-function steering wheel remains, while the infotainment system gets a new interface and graphics. The Spider followed the closed coupe model six months later,

Latest in the line of special versions of Ferrari’s V8 models, the 488 Pista was launched at the 2018 Geneva Show but it has taken until now before UK customers have got their hands on the cars they ordered all that time ago. Compared to the regular Ferrari 488 GTB, the 488 Pista is 90 kg lighter at 1280kg dry, features a 20 percent improved aerodynamic efficiency and makes 49hp more from its twin-turbo V8 that now produces 711hp (720PS). These are some stunning specs to be honest, especially when you consider just how good the car it’s based upon is. Ferrari claims a 0-62mph (100km/h) in 2.85 seconds, 0-124mph (200km/h) in 7.6 seconds and a top speed of over 211mph (340km/h). Ferrari has opted to call the new special series sports car “Pista”, which is Italian for ‘track’, joining a celebrated lineup of hardcore models that includes the Challenge Stradale, the 430 Scuderia and the 458 Speciale. The whole bodywork has been reshaped, with the designers using innovations such as the S-Duct at the front and the unique edges of the front bumper and side sills that guide the air flow in -apparently- all the right places. The 3.9-litre V8 engine is essentially the same unit found in the Challenge race car and features specific valves and springs, a new cam profile, strengthened pistons and cylinder heads shorter inlet ducts, radiators with an inverted rake, a larger intercooler and more. It’s also 18kg lighter than the standard engine. For the first time ever in a Ferrari, the new 488 Pista can be fitted with a set of optional single-piece carbon-fibre wheels that are around 40 percent lighter than the GTB’s standard rims. A new generation of Ferrari’s Side Slip Control System is also present (SSC 6.0) because who doesn’t like to slide around a Ferrari with some help from the gods of Maranello. The 488 Pista is not a limited production model and was offered alongside the regular 488 GTB until it went out of production.

The F8 Tributo was a surprise newcomer at the 2019 Geneva Show, and the successor to the 488 GTB and the most powerful mid-engined V8 berlinetta in the history of the brand. The new Ferrari F8 Tributo is powered by the company’s twin-turbo 3.9-litre V8 engine, here tuned to produce 710 bhp and 568lb/ft (770Nm) of peak torque. The numbers are the exact same with the special 488 Pista. Ferrari claims that the new F8 Tributo is capable of a 0-62mph (100km/h) in 2.9 seconds, with 0-124mph (200km/h) in 7.8 seconds before hitting a top speed of 211mph (340km/h). It’s not a secret that the new F8 Tributo is the latest evolution of the aluminium 458 platform, with Ferrari saying that their latest mid-engine berlinetta is “a bridge to a new design language”. The new supercar blends in new design elements with aero features such as an S-Duct at the front, which on its own increases downforce by 15 percent compared to a standard 488 GTB. The rear end of Ferrari’s McLaren 720S rival marks the return of the classic Ferrari twin light clusters, while the engine cover is now made out of Lexan and features louvres to extract hot air and remind us of the iconic F40. The chassis of the new F8 Tributo employs Ferrari’s latest version of the Side Slip Angle Control traction management system, which aims to make sliding the car around manageable even for the less experienced drivers. The changes over the 488 GTB are less prominent once you look inside the cabin; the layout of the redesigned dashboard remains the same as before, only now there are completely new door panels and a centre console, as well as a new steering wheel design. The passenger gets a 7-inch touchscreen display. First deliveries of the new Ferrari F8 Tributo started earlier in 2020 and production ceased in 2022.

The Ferrari SF90 Stradale (Type F173) is a mid-engine PHEV (Plug-in Hybrid Electric Vehicle) sports car produced by the Italian automobile manufacturer Ferrari. The car shares its name with the SF90 Formula One car with SF90 standing for the 90th anniversary of the Scuderia Ferrari racing team and “Stradale” meaning “made for the road”. The car has a 7.9 kWh lithium-ion battery for regenerative braking, giving the car 26 km (16 mi) of electric range. The car comes with four driving modes depending on road conditions. The modes are changed by the eManettino knob present on the steering wheel. The eDrive mode runs the car only on the electric motors. The Hybrid mode runs the car on both the internal combustion engine and the electric motors and is the car’s default mode. In this mode, the car’s onboard computer (called control logic) also turns off the engine if the conditions are ideal in order to save fuel while allowing the driver to start the engine again. The Performance mode keeps the engine running in order to charge the batteries and keeps the car responsive in order for optimum performance. The Qualify mode uses the powertrain to its full potential. The control logic system makes use of three primary areas: the high-voltage controls of the car (including the batteries), the RAC-e (Rotation Axis Control-electric) torque vectoring system, and the MGUK along with the engine and gearbox. The SF90 Stradale is equipped with three electric motors, adding a combined output of 220 PS to a twin-turbocharged V8 engine rated at a power output of 780 PS at 7,500 rpm. The car is rated at a total output of 1,000 PS at 8,000 rpm and a maximum torque of 800 Nm (590 lb/ft) at 6,000 rpm. The engine is an evolution of the unit found in the 488 Pista and the upcoming F8 Tributo models. The engine’s capacity is now 3,990 cc by increasing each cylinder bore to 88 mm. The intake and exhaust of the engine have been completely modified. The cylinder heads of the engine are now narrower and the all-new central fuel injectors run at a pressure of 350 bar (5,100 psi). The assembly for the turbochargers is lower than that of the exhaust system and the engine sits 50 mm (2.0 in) lower in the chassis than the other mid-engine V8 models in order to maintain a lower centre of gravity. The engine utilises a smaller flywheel and an inconel exhaust manifold. The front wheels are powered by two electric motors (one for each wheel), providing torque vectoring. They also function as the reversing gear, as the main transmission (eight-speed dual-clutch) does not have a reversing gear. The engine of the SF90 Stradale is mated to a new 8-speed dual-clutch transmission. The new transmission is 10 kg (22 lb) lighter and more compact than the existing 7-speed transmission used by the other offerings of the manufacturer partly due to the absence of a dedicated reverse gear since reversing is provided by the electric motors mounted on the front axle. The new transmission also has a 30% faster shift time (200 milliseconds). A 16-inch curved display located behind the steering wheel displays various vital statistics of the car to the driver. The car also employs a new head-up display that would reconfigure itself according to the selected driving mode. The steering wheel is carried over from the 488 but now features multiple capacitive touch interfaces to control the various functions of the car. Other conventional levers and buttons are retained. The interior will also channel sound of the engine to the driver according to the manufacturer. The SF90 Stradale employs eSSC (electric Side Slip Control) which controls the torque distribution to all four wheels of the car. The eSSC is combined with eTC (electric Tractional Control), a new brake-by-wire system which combines the traditional hydraulic braking system and electric motors to provide optimal regenerative braking and torque vectoring. The car’s all-new chassis combines aluminium and carbon fibre to improve structural rigidity and provide a suitable platform for the car’s hybrid system. The car has a total dry weight of 1,570 kg (3,461 lb) after combining the 270 kg (595 lb) weight of the electric system. Ferrari states that the SF90 Stradale is capable of accelerating from a standstill to 100 km/h (62 mph) in 2.5 seconds, 0–200 km/h (124 mph) in 6.7 seconds and can attain a top speed of 340 km/h (211 mph). It is the fastest Ferrari road car on their Fiorano Circuit as of 2020, seven tenths of a second faster than the LaFerrari.  The manufacturer claims that the SF90 Stradale can generate 390 kg (860 lb) of downforce at 250 km/h (155 mph) due to new findings in aero and thermal dynamics. The main feature of the design is the twin-part rear wing which is an application of the drag reduction system (DRS) used in Formula One. A fixed element in the wing incorporates the rear light, the mobile parts of the wing (called “shut off Gurney” by the manufacturer) integrate into the body by using electric actuators in order to maximise downforce. The SF90 Stradale uses an evolution of Ferrari’s vortex generators mounted at the front of the car. The car employs a cab-forward design in order to utilise the new aerodynamic parts of the car more effectively and in order to incorporate radiators or the cooling requirements of the hybrid system of the car. The design is a close collaboration between Ferrari Styling Centre and Ferrari engineers. The rear-end of the car carries over many iconic Ferrari Styling elements such as the flying buttresses. The engine cover has been kept as low as possible in order to maximise airflow. According to the car’s lead designer, Flavio Manzoni, the car’s design lies in between that of a spaceship and of a race car. The rear side-profile harkens back to the 1960s 330 P3/4. Deliveries in the UK started in late 2020 and so numbers here are gradually building up.

The Ferrari 296 (Type F171)is a sports car built since 2022 by the Italian company Ferrari. The 296 is a two-seater, offered as a GTB coupé and a GTS folding hard-top convertible. It is a plug-in hybrid with a rear mid-engine, rear-wheel-drive layout and its power train combines a twin-turbocharged 120-degree block-angle V6 with an electric drive fitted in between the engine and gearbox. The 296 can be driven in electric-only mode for short distances, to comply with use in urban zero-emission zones. Unveiled on 24 June 2021, the 296 is Ferrari’s first stock model with 6-cylinders other than the Dino 206 GT, 246 GT and 246 GTS cars produced by Ferrari but sold under the Dino marque. Its power pack puts out a combined 830 PS, giving the 296 a power-to-weight ratio of 560 hp/ton. The 296 GTB was presented as the first “real Ferrari with just six cylinders on it” on 24 June 2021. Previously, such models were both designed and built by Ferrari, but marketed as a new, entry-level Dino brand, below Ferrari’s exclusively V12-model policy, until 1974. The new car went on sale in 2022. The 296 in the model name reprises the original Dino’s naming scheme, indicating the engine’s displacement and the number of cylinders. GTB stands for Gran Turismo Berlinetta. It remains a current model.

Final Ferrari here was the Roma, the well-received 2 + 2 coupe that has recently begat an open-topped stablemate.

FORD

The Ford GT began life as a concept car designed in anticipation of the automaker’s centennial year and as part of its drive to showcase and revive its “heritage” names such as Mustang and Thunderbird. At the 2002 North American International Auto Show, Ford unveiled a new GT40 Concept car. Camilo Pardo, the then head of Ford’s “Living Legends” studio, is credited as the chief designer of the GT and worked under the guidance of J Mays. Carroll Shelby, the original designer of the Shelby GT 500, was brought in by Ford to help develop the GT; which included performance testing of the prototype car. While under development, the project was called Petunia. The GT is similar in outward appearance to the original GT40, but is bigger, wider, and most importantly 4 in (100 mm) taller than the original’s 40 in (100 cm) overall height; as a result, a potential name for the car was the GT44. Although the cars are visually related, structurally, there is no similarity between the modern GT and the 1960s GT40 that inspired it. After six weeks from the unveiling of the GT40 concept, Ford announced a limited production run of the car. Three pre-production cars were shown to the public in 2003 as part of Ford’s centenary celebrations, and delivery of the production version called simply the Ford GT began in the fall of 2004. As the Ford GT was built as part of the company’s 100th anniversary celebration, the left headlight cluster was designed to read “100”. A British company, Safir Engineering, who built continuation GT40 cars in the 1980s, owned the “GT40” trademark at that time. When production of the continuation cars ended, they sold the excess parts, tooling, design, and trademark to a small Ohio based company called Safir GT40 Spares. This company licensed the use of the “GT40” trademark to Ford for the initial 2002 show car. When Ford decided to put the GT40 concept to production stage, negotiations between the two firms failed as Ford did not pay the US$40 million the owners of the name demanded. Thus, the production cars are simply called the GT. The GT was produced for the 2005 and 2006 model years. The car began assembly at Mayflower Vehicle Systems (MVS) in Norwalk, Ohio and was painted and continued assembly at Saleen Special Vehicles (SSV) facility in Troy, Michigan, through contract by Ford. The GT is powered by an engine built at Ford’s Romeo Engine Plant in Romeo, Michigan. Installation of the engine and transmission along with seats and interior finishing was handled in the SVT building at Ford’s Wixom, Michigan plant. Of the 4,500 cars originally planned, approximately 100 were to be exported to Europe, starting in late 2005. An additional 200 cars were destined for sale in Canada. Production ended in September 2006 without reaching the planned production target. Approximately 550 cars were built in 2004, nearly 1,900 in 2005, and just over 1,600 in 2006, for a grand total of 4,038 cars. The final 11 car bodies manufactured by Mayflower Vehicle Systems were disassembled, and the frames and body panels were sold as service parts. The Wixom Assembly Plant has stopped production of all models as of May 31, 2007. Sales of the GT continued into 2007, from cars held in storage and in dealer inventories.

FRAZER NASH

The Frazer Nash Le Mans Replica, and its evolution, the Frazer Nash Le Mans Replica Mk2, is a sports car, designed, developed and built by British manufacturer Frazer Nash, between 1949 and 1954.

GMA

The Gordon Murray Automotive Type 50 or GMA T.50 is a sports car manufactured by Gordon Murray Automotive. Designed by Gordon Murray and inspired by the McLaren F1, the T.50 is powered by an all-new 3,994 cc (4.0 L) naturally aspirated V12 engine developed by Cosworth. The engine is rated at 663 PS (654 bhp) at 11,500 rpm with a maximum torque of 467 Nm (344 lb/ft) at 9,000 rpm. The T.50 achieves a dry weight of 997 kg (2,198 lb), making it lighter than the vast majority of vehicles in its class, with the naturally aspirated V12 weighing only 178 kg (392 lb), and the chassis is 30 kg (66 lb) lighter than the McLaren F1. As a result, the T.50 features one of the highest power-to-weight ratios amongst its class at 672 hp per tonne, while its engine attains a specific output of 163.7 hp per litre. A distinctive feature of the GMA T.50 is the 8.5 kW 40 cm aerodynamic fan integrated into the rear of the car, powered by a 48 volt electrical motor. Inspired by the Brabham BT46B Formula One car, it is purpose-built to significantly improve the ground effect of the T.50. As the T.50 makes use of very aggressive and steep angled rear diffusers, this in turn creates substantial turbulent or semi-stalled air passing over the diffuser when the T.50 has its fan inactive. By utilising the integrated aerodynamic fan, the T.50 can suck the air under the car at a 90-degree angle and provide a significant increase in overall downforce as it provides a laminar flow of air passing over the rear diffuser, thus, creating a greater level of suction in tandem with the Venturi effect, created underneath the car, ahead of the steep rear diffusers. This allows the T.50 to control the boundary layer and turbulent vortices underneath the car, significantly improving downforce. As a result of the T.50’s fan-assisted aerodynamic design, the need for any aerodynamic package on the front or rear of the T.50, such as a splitter, a wing or an aggressive aerodynamic design are considered ineffective in providing further downforce and are thus considered negligible, allowing a free form and flowing exterior design. The T.50 does make use of active aero spoilers however, that operate in conjunction with the aerodynamic fan. The active aero and fan functionality of the car is dependent on the driver selected mode which is provided in six presets made available in the cockpit of the car. The fan assisted aero design allows for a 30% increase in downforce when a ‘high downforce’ mode is selected, channelling air through aero ducts perpendicular to the airflow underneath the car, providing a high suction ground effect. Furthermore, under braking the T.50 provides 100% additional downforce by extending the active spoilers to a 45-degree angle of attack and utilising diffuser ducts. The T.50 can also achieve reductions in drag by selecting the specialised mode presets of ‘streamline’ and ‘Vmax’ modes, allowing for a 12.5% reduction in overall drag. The car has been noted for its numerous similarities to the McLaren F1, produced between 1992 and 1998, which Gordon Murray conceptualised and co-designed. The T.50 has been described by Gordon Murray Automotive as being the “spiritual successor to the Murray-devised McLaren F1”. The T.50 shares familiar features with the F1: a central driving position with two passenger seats flanking the driver, a six-speed manual gearbox, V12 powertrain, small opening ‘ticket’ windows in the otherwise fixed side window and dihedral ‘wing’ doors. The T.50 addresses many of the design and engineering inadequacies of the 90s supercar, many of those the result of period design practices and time and budget constraints enforced by McLaren. As recorded by Murray “the spine is 50 mm too wide, the headlamps are like glow worms in a jar, the air-con was hopeless, the brakes squeak, the clutch needs adjusting every 5,000 miles, the fuel tank bag replacing every five years, loading luggage in the lockers was a pain. This all stuck in my head”. GMA plans to build 100 customer cars at its Surrey production site. Each car cost £2.36 million before local taxes and all of the planned 100 road spec units were sold within 48 hours of its global premiere. As of August 2020 there are to be 13 GMA T.50 prototypes to pass crash, durability and emission regulations.

JAGUAR

Jaguar stunned the world with the XK120 that was the star of the Earls Court Motor Show in 1948. Seen in open two seater form, the car was a testbed and show car for the new Jaguar XK engine. The display car was the first prototype, chassis number 670001. It looked almost identical to the production cars except that the straight outer pillars of its windscreen would be curved on the production version. The roadster caused a sensation, which persuaded Jaguar founder and design boss William Lyons to put it into production. Beginning in 1948, the first 242 cars wore wood-framed open 2-seater bodies with aluminium panels. Production switched to the 112 lb heavier all-steel in early 1950. The “120” in the name referred to the aluminium car’s 120 mph top speed, which was faster with the windscreen removed. This made it the world’s fastest production car at the time of its launch. Indeed, on 30 May 1949, on the empty Ostend-Jabbeke motorway in Belgium, a prototype XK120 timed by the officials of the Royal Automobile Club of Belgium achieved an average of runs in opposing directions of 132.6 mph with the windscreen replaced by just one small aeroscreen and a catalogued alternative top gear ratio, and 135 mph with a passenger-side tonneau cover in place. In 1950 and 1951, at a banked oval track in France, XK120 roadsters averaged over 100 mph for 24 hours and over 130 mph for an hour, and in 1952 a fixed-head coupé took numerous world records for speed and distance when it averaged 100 mph for a week. Roadsters were also successful in racing and rallying. The first production roadster, chassis number 670003, was delivered to Clark Gable in 1949. The XK120 was ultimately available in two open versions, first as an open 2-seater described in the US market as the roadster (and designated OTS, for open two-seater, in America), and from 1953 as a drophead coupé (DHC); as well as a closed, or fixed head coupé (FHC) from 1951. A smaller-engined version with 2-litres and 4 cylinders, intended for the UK market, was cancelled prior to production.

There were lots of E Types here, of course. The Series 1 was introduced, initially for export only, in March 1961. The domestic market launch came four months later in July 1961. The cars at this time used the triple SU carburetted 3.8-litre six-cylinder Jaguar XK6 engine from the XK150S. Earlier built cars utilised external bonnet latches which required a tool to open and had a flat floor design. These cars are rare and more valuable. After that, the floors were dished to provide more leg room and the twin bonnet latches moved to inside the car. The 3.8-litre engine was increased to 4,235 cc in October 1964. The 4.2-litre engine produced the same power as the 3.8-litre (265 bhp) and same top speed (150 mph), but increased torque approximately 10% from 240 to 283 lb/ft. Acceleration remained pretty much the same and 0 to 60 mph times were around 6.4 seconds for both engines, but maximum power was now reached at 5,400 rpm instead of 5,500 rpm on the 3.8-litre. That all meant better throttle response for drivers that did not want to shift down gears. The 4.2-litre’s block was completely redesigned, made longer to accommodate 5 mm (0.20 in) larger bores, and the crankshaft modified to use newer bearings. Other engine upgrades included a new alternator/generator and an electric cooling fan for the radiator. Autocar road tested a UK spec E-Type 4.2 fixed head coupé in May 1965. The maximum speed was 153 mph, the 0–60 mph time was 7.6 seconds and the 1⁄4 mile from a standing start took 15.1 seconds. They summarised it as “In its 4.2 guise the E-Type is a fast car (the fastest we have ever tested) and offers just about the easiest way to travel quickly by road.”. Motor magazine road tested a UK spec E-Type 4.2 fixed head coupé in Oct 1964. The maximum speed was 150 mph, the 0–60 mph time was 7 seconds and the 1⁄4 mile time was 14.9 seconds. They summarised it as “The new 4.2 supersedes the early 3.8 as the fastest car Motor has tested. The absurd ease which 100 mph can be exceeded in a 1⁄4 mile never failed to astonish. 3,000 miles (4,828 km) of testing confirms that this is still one of the world’s outstanding cars”. All E-Types featured independent coil spring rear suspension designed and developed by R J Knight with torsion bar front ends, and four wheel disc brakes, in-board at the rear, all were power-assisted. The Coventry engineers spared nothing with regards to high automotive technology in braking. Like several British car builders of the middle and late 1950s, the four-wheel disc brakes were also used in that era by Austin-Healey, MG,putting the British far ahead of Ferrari, Maserati, Alfa Romeo, Porsche, and Mercedes-Benz. Even Lanchester tried an abortive attempt to use copper disc brakes in 1902.[40] Jaguar was one of the first vehicle manufacturers to equip production cars with 4 wheel disc brakes as standard from the XK150 in 1958. The Series 1 (except for late 1967 models) can be recognised by glass-covered headlights (up to 1967), small “mouth” opening at the front, signal lights and tail-lights above bumpers and exhaust tips under the number plate in the rear. 3.8-litre cars have leather-upholstered bucket seats, an aluminium-trimmed centre instrument panel and console (changed to vinyl and leather in 1963), and a Moss four-speed gearbox that lacks synchromesh for first gear (“Moss box”) on all except very last cars. 4.2-litre cars have more comfortable seats, improved brakes and electrical systems, and,obviously, an all-synchromesh Jaguar designed four-speed gearbox. 4.2-litre cars also have a badge on the boot proclaiming “Jaguar 4.2 Litre E-Type” (3.8 cars have a simple “Jaguar” badge). Optional extras included chrome spoked wheels and a detachable hard top for the OTS. When leaving the factory the car was originally fitted with Dunlop 6.40 × 15-inch RS5 tyres on 15 × 5K wire wheels (with the rear fitting 15 × 5K½ wheels supplied with 6.50 X15 Dunlop Racing R5 tyres in mind of competition). Later Series One cars were fitted with Dunlop 185 – 15 SP41 or 185 VR 15 Pirelli Cinturato as radial ply tyres. A 2+2 version of the fastback coupé was added in 1966. The 2+2 offered the option of an automatic transmission. The body is 9 in (229 mm) longer and the roof angles are different. The roadster and the non 2+2 FHC (Fixed Head Coupé) remained as two-seaters. Less widely known, right at the end of Series 1 production, but prior to the transitional “Series 1½” referred to below, a small number of Series 1 cars were produced with open headlights. These Series 1 cars had their headlights modified by removing the covers and altering the scoops they sit in, but these Series 1 headlights differ in several respects from those later used in the Series 1½ (or 1.5), the main being they are shorter at 143 mm from the Series 1½ at 160 mm. Production dates on these machines vary but in right-hand drive form production has been verified as late as July 1968. They are not “rare” in the sense of the build of the twelve lightweights, but they are certainly uncommon; they were not produced until January 1967 and given the foregoing information that they were produced as late as July 1968, it appears that there must have been an overlap with the Series 1.5 production, which began in August 1967 as model year 1968 models. These calendar year/model year Series 1 E-Types are identical to other 4.2-litre Series 1 examples in every respect except for the open headlights; all other component areas, including the exterior, the interior, and the engine compartment are the same, with the same three SU carburettors, polished aluminium cam covers, centre dash toggle switches, etc. Following the Series 1 there was a transitional series of cars built in 1967–68 as model year 1968 cars, unofficially called “Series 1½.” Due to American pressure the new features were not just open headlights, but also different switches (black rocker switches as opposed to the Series 1 toggle switches), de-tuning for emissions (using two Zenith-Stromberg carburettors instead of the original three SUs) for US models, ribbed cam covers painted black except for the top brushed aluminium ribbing, bonnet frames on the OTS that have two bows, and other changes. Series 1½ cars also have twin cooling fans and adjustable seat backs. The biggest change between 1961–1967 Series 1 E-Types and the 1968 Series 1.5 was the reduction in the number of carburettors from 3 to just 2 (North America), resulting in a loss in horsepower. Series 2 features were gradually introduced into the Series 1, creating the unofficial Series 1½ cars, but always with the Series 1 body style. A United States federal safety law affecting 1968 model year cars sold in the US was the reason for the lack of headlight covers and change in dash switch design in the “Series 1.5” of 1968. An often overlooked change, one that is often “modified back” to the older style, is the wheel knock-off “nut.” US safety law for 1968 models also forbade the winged-spinner knockoff, and any 1968 model year sold in the US (or earlier German delivery cars) should have a hexagonal knockoff nut, to be hammered on and off with the assistance of a special “socket” included with the car from the factory. This hexagonal nut carried on into the later Series 2 and 3. The engine configuration of the US Series 1.5s was the same as is found in the Series 2. An open 3.8-litre car, actually the first such production car to be completed, was tested by the British magazine Motor in 1961 and had a top speed of 149.1 mph and could accelerate from 0 to 60 mph in 7.1 seconds. A fuel consumption of 21.3 mpg was recorded. The test car cost £2,097 including taxes.The cars submitted for road test by the motoring journals of the time (1961) such as Motor, Autocar and Autosport magazines were prepared by the Jaguar works. This work entailed engine balancing and subtle tuning work such as gas-flowing checking the cylinder heads but otherwise production built engines. Both of the well-known 1961 road test cars: the E-Type coupé Reg. No. 9600 HP and E-Type Convertible Reg. No. 77 RW, were fitted with Dunlop Racing Tyres on test, which had a larger rolling diameter and lower drag coefficient. This goes some way to explaining the 150 mph (240 km/h) maximum speeds that were obtained under ideal test conditions. The maximum safe rev limit for standard 6-cylinder 3.8-litre E-Type engines is 5,500 rpm. The later 4.2-Litre units had a red marking on the rev counter from just 5,000 rpm. Both 3.8 test cars may have approached 6,000 rpm in top gear when on road test, depending on final drive ratio. Production numbers were as follows: 15,490 of the 3.8s, 17,320 of the 4.2s and 10,930 of the 2+2s. And by body style there were 15,442 of the FHC, 17,378 of the OTS and 5,500 of the 2+2, making a total of 38,419 of the Series 1 car.

The E-Type Series 3 was introduced in 1971, with a new 5.3 L Jaguar V12 engine, uprated brakes and standard power steering. Optionally an automatic transmission, wire wheels and air conditioning were available. The V12 was equipped with four Zenith carburettors, and as introduced produced a claimed 272 bhp, more torque, and a 0–60 mph acceleration of less than seven seconds. The short wheelbase FHC body style was discontinued, with the Series 3 available only as a convertible and 2+2 coupé. The newly used longer wheelbase now offered significantly more room in all directions. The Series 3 is easily identifiable by the large cross-slatted front grille, flared wheel arches, wider tyres, four exhaust tips and a badge on the rear that proclaims it to be a V12. The first published road test of the series 3 was in Jaguar Driver, the club magazine of the Jaguar Drivers’ Club, the only owners club to be officially sanctioned by Sir William Lyons and Jaguar themselves. The road test of a car provided by Jaguar was published ahead of all the national and international magazines. Cars for the US market were fitted with large projecting rubber bumper over-riders (in 1973 these were on front, in 1974 both front and rear) to meet local 5 mph impact regulations, but those on European models were considerably smaller. US models also have side indicator repeats on the front wings. There were also a very limited number of six-cylinder Series 3 E-Types built. These were featured in the initial sales procedure but the lack of demand stopped their production. The V12 Open Two Seater and V12 2+2 were factory fitted with Dunlop E70VR − 15-inch tyres on 15 × 6K wire or solid wheels. The final production E-Type OTS Roadster was built in June 1974. Total production was 15,290.

Few would have guessed that the XJS would run for over 20 years, but eventually it came time for its replacement, and the car charged with so doing was the XK8. Development began in 1992, with design work having starting earlier, in late 1991. By October 1992 a design was chosen and later frozen for production in 1993. Prototypes were built from December 1993 after the X100 was given formal approval and design patents were filed in June 1994. Development concluded in 1996, at which point the car was launched. The first-generation XK series shares its platform with the Aston Martin DB7, and both cars are derived from the Jaguar XJS, though the platform has been extensively changed. One of the revisions is the use of the second generation of Jaguar’s independent rear suspension unit, taken from the XJ40. The XK8 was available in coupé or convertible body styles and with the then new 4.0-litre Jaguar AJ-V8 engine. In 1998 the XKR was introduced with a supercharged version of the engine. 2003 the engines were replaced by the 4.2-litre AJ34 engines in both the normally aspirated and supercharged versions. Equipment levels were generous and there was a high standard of fit and finish. Both models came with all-leather interior, burl walnut trim, and side airbags. Jeremy Clarkson, during a Top Gear test-drive, likened the interior of the original XK8 to sitting inside Blenheim Palace. The model ran for 10 years before being replaced by the X150 model XK.

The second generation of the XK debuted in 2005 at the Frankfurt Motor Show in Germany, styled by Jaguar’s chief designer Ian Callum. The X150’s grille was designed to recall the 1961 E-Type. The XK is an evolution of the Advanced Lightweight Coupé (ALC) introduced at the 2005 North American International Auto Show. The XK features a bonded and riveted aluminium chassis shared with the XJ and body panels, both a first for a Jaguar grand tourer. Compared to the XK (X100), the XK (X150) is 61.0 mm (2.4 in) wider and is 162.6 mm (6.4 in) longer. It is also 91 kg (200 lb) lighter resulting in performance and fuel consumption improvements. Unlike the X100, the X150 has no wood trim on the interior offered as standard equipment. The interior featured steering column mounted shift paddles. A more powerful XKR version having a supercharged variant of the engine was introduced in 2007. The XK received a facelift in 2009,[10] with minor alterations to front and rear lights and bumper designs, together with the introduction of a new 5.0-litre V8 for both the naturally aspirated XK and the supercharged XKR. The interior also received some changes, in particular the introduction of the XF style rotary gear selector mated to the new ZF automatic transmission. The XK received a second and more minor facelift in 2011 with new front bumper and light design, which was presented at the New York Auto Show. A higher performance variant of the XKR, the XKR-S, was introduced at the Geneva Motor Show in 2012. The XKR-S gained an additional 40 bhp over the XKR bringing the 0-60 mph acceleration time down to 4.4 seconds and the top speed up to 300 km/h (186 mph). A convertible version of the XKR-S was introduced in 2012. Production of the XK ended in July 2014 without a replacement model.

The Jaguar Project Seven was first seen in the summer of 2013, more of an indication of what could be done with the new F Type rather than as something which was going to be produced, such was the clamour from enthusiasts that Jaguar decided to build a limited run of them, and even at a starting price of £130,000, there were more people who wanted to buy one than cars that Jaguar planned to make, with the car selling out before it officially went on sale. Just 250 will be built, 80 available to buyers in the UK, 50 in Germany and the balance to the Americans, who, generally were the first to get their cars. The Seven in the name refers to Jaguar’s seven Le Mans wins (two of them with the help of Ecurie Ecosse, of course). Visually, it is easy to recognise from a standard F Type, with its abbreviated screen, its new front bumper, many aero mods (carbonfibre splitter, blade-like side skirts, rear diffuser and deck-mounted rear wing) and its nose stripes and racing roundels. The owner explained that he is not allowed to put a number on the roundel for road use, and he is also agonising over whether to put on a front number plate, as it would spoil the looks of the car. The Project 7 starts as a standard V8 drophead, with its 5.0-litre supercharged engine modified to produce 567bhp, which is 25bhp more than an F-Type R Coupé and 516lb ft of torque (15lb ft more). Proportionally speaking, these aren’t huge increases, but they’re delivered via unique throttle maps that let you feel the extra energy from around 2500rpm and these figures do make this the most powerful Jaguar ever made. Combine this with the benefits of a 45kg weight reduction (35kg of this comes from that rather ungainly “get you home” hood and the seats have race-bred carbonfibre shells) and you get an F-Type capable of the 0-60mph sprint in 3.8sec. The top speed is electronically limited to 186mph or 300km/h, as with other F-Types. With the exhaust butterflies open (there’s a special console switch), the car emits a superb growl-bark that turns into a magnificent crackle on the overrun. It’s the one thing that makes you want to slow down, though we did not get the real benefit of this as the car was driven, carefully around the rough and cobbled surfaces of the Square. A lot of the engineering effort spend on developing the car was in rebalancing the suspension and aerodynamics for high-speed duty. Font negative camber was increased from 0.5 to 1.5deg, to encourage the front wheels to dig in, and rear torque vectoring – differential braking of the rear wheels – is there to make the car turn easily. The car’s rear-biased aerodynamic downforce was addressed by fitting side skirts and a large front splitter, while slightly reducing the effectiveness (and drag) of the bootlid wing. Project Seven is fitted with all the top-end running gear: eight-speed Quickshift transmission, electronic differential, carbon-ceramic brakes, unique-tune adaptive dampers and its own special settings for engine management and chassis stability control. The Project 7 also has unique springs and anti-roll bars, the most prominent feature being front springs that are a stonking 80% stiffer, to cope with the potential force generated by the brakes and withstand turn-in loads at high speed on the soft standard Continental Force tyres. Engineers also moved the Sport and standard suspension settings further apart, to provide good options for short and long-distance use. The modifications are apparently most obvious on track, and Jaguar SVO reckon most owners will take their cars there as part of the limited mileage that they will probably cover in an average year.

Also here was the regular F Type, Jaguar’s most recent sportscar offering.

LAMBORGHINI

Which small boy (and perhaps car loving girl) did not lust after a Countach back in the 1970s and 1980s. A dramatic looking car, this was the stuff of dreams that you would only ever see at the London or NEC Motor Shows. Countach first made an appearance, as a concept in 1971, but it was 1973 before the production car made its debut, and despite unfortunate timing with fuel shortages and a recession, and a number of financial problems for its maker, the car sold well throughout its production life. The Countach entered production as the LP400 with a 3929 cc engine delivering 370 hp. The first production Countach was delivered to an Australian in 1974. Externally, little had altered from the final form of the prototype except at the rear, where conventional lights replaced the futuristic light clusters of the prototype. The styling had become rather more aggressive than Gandini’s original conception, with the required large air scoops and vents to keep the car from overheating, but the overall shape was still very sleek. The original LP400 rode on the quite narrow tyres of the time, but their narrowness and the slick styling meant that this version had the lowest drag coefficient of any Countach model. The emblems at the rear simply read “Lamborghini” and “Countach”, with no engine displacement or valve arrangement markings as is found on later cars. By the end of 1977, the company had produced 158 Countach LP400s. In 1978, a new LP400 S model was introduced. Though the engine was slightly downgraded from the LP400 model (350 bhp), the most radical changes were in the exterior, where the tyres were replaced with 345/35R15 Pirelli P7 tyres; the widest tyres available on a production car at the time, and fibreglass wheel arch extensions were added, giving the car the fundamental look it kept until the end of its production run. An optional V-shaped spoiler was available over the rear deck, which, while improving high-speed stability, reduced the top speed by at least 16 km/h (10 mph). Most owners ordered the wing. The LP400 S handling was improved by the wider tyres, which made the car more stable in cornering. Aesthetically, some prefer the slick lines of the original, while others prefer the more aggressive lines of the later models, beginning with the LP400 S. The standard emblems (“Lamborghini” and “Countach”) were kept at the rear, but an angular “S” emblem was added after the “Countach” on the right side. 1982 saw another improvement, this time giving a bigger, more powerful 4754 cc engine. The bodywork was unaltered, however the interior was given a refresh. This version of the car is sometimes called the 5000 S, which may cause confusion with the later 5000 QV. 321 of these cars were built. Two prototypes of the 1984 Countach Turbo S were built by Lamborghini, of which one is known to exist. The Turbo S weighed 1,515 kg (3,340 lb), while its 4.8 litre twin-turbo V12 had a claimed maximum power output of 758 PS and a torque output of 876 N·m (646 lb·ft), giving the car an acceleration of 0–100 km/h (0–62 mph) in 3.7 seconds and a top speed of 335 km/h (208 mph). A turbo adjuster, located beneath the steering wheel, could be used to adjust the boost pressure from 0.7 bar to 1.5 bar at which the engine performed its maximum power output. The Turbo S has 15″ wheels with 255/45 tyres on the front and 345/35 on the rear. In 1985 the engine design evolved again, as it was bored and stroked to 5167 cc and given four valves per cylinder—quattrovalvole in Italian, hence the model’s name, Countach 5000 Quattrovalvole or 5000 QV in short. The carburettors were moved from the sides to the top of the engine for better breathing—unfortunately this created a hump on the engine deck, reducing the already poor rear visibility to almost nothing. Some body panels were also replaced by Kevlar. In later versions of the engine, the carburettors were replaced with fuel injection. Although this change was the most notable on the exterior, the most prominent change under the engine cover was the introduction of fuel injection, with the Bosch K-Jetronic fuel injection, providing 414 bhp, rather than the six Weber carburettors providing 455 bhp. As for other markets, 1987 and 1988 model Quattrovalvoles received straked sideskirts. 610 cars were built.

At a time when the company was financed by the Swiss-based Mimran brothers, Lamborghini began development of what was codenamed Project 132 in June 1985 as a replacement for the Countach model. The brief stated that its top speed had to be at least 315 km/h (196 mph). The design of the car was contracted to Marcello Gandini, who had designed its two predecessors. When Chrysler bought the company in 1987, providing money to complete its development, its management was uncomfortable with Gandini’s designs and commissioned its design team in Detroit to execute a third extensive redesign, smoothing out the trademark’s sharp edges and corners of Gandini’s original design, and leaving him famously unimpressed. In fact, Gandini was so disappointed with the “softened” shape that he would later realise his original design in the Cizeta-Moroder V16T. The car became known as the Diablo, carrying on Lamborghini’s tradition of naming its cars after breeds of fighting bulls. The Diablo was named after a ferocious bull raised by the Duke of Veragua in the 19th century, famous for fighting an epic battle with ‘El Chicorro’ in Madrid on July 11, 1869 In the words of Top Gear presenter Jeremy Clarkson, the Diablo was designed “solely to be the biggest head-turner in the world.” The Diablo was presented to the public for sale on January 21, 1990. Its power came from a 5.7 litre 48-valve version of the existing Lamborghini V12 featuring dual overhead cams and computer-controlled multi-point fuel injection, producing a maximum output of 499 PS and 580 N·m (428 lb/ft) of torque. The vehicle could reach 100 km/h in about 4.5 seconds, with a top speed of 202 mph. The Diablo was rear-wheel drive and the engine was mid-mounted to aid its weight balance. The Diablo came better equipped than the Countach; standard features included fully adjustable seats and steering wheel, electric windows, an Alpine stereo system, and power steering from 1993 onwards. Anti-lock brakes were not initially available, although they would eventually be used. A few options were available, including a custom-moulded driver’s seat, remote CD changer and subwoofer, rear spoiler, factory fitted luggage set and an exclusive Breguet clock for the dash. The Diablo VT was introduced in 1993. Although the VT differed from the standard Diablo in a number of ways, by far the most notable change was the addition of all wheel drive, which made use of a viscous centre differential (a modified version of LM002’s 4WD system). This provided the new nomenclature for the car (VT stands for viscous traction). The new drivetrain could direct up to 25% of the torque to the front wheels to aid traction during rear wheel slip, thus significantly improving the handling characteristics of the car. Other improvements debuting on the VT included front air intakes below the driving lamps to improve brake cooling, larger intakes in the rear arches, a more ergonomic interior with a revised dashboard, electronically adjustable dampers, four-piston brake calipers, power steering, and minor engine refinements. Many of these improvements, save the four-wheel drive system, soon transferred to the base Diablo, making the cars visually nearly identical. Further updates would follow before the car gave way to the Murcielago in 2001. The Diablo sold in greater numbers than its predecessor with 2898 examples being made during its 11 year production life. There were several here, including the VT and the SV, a few of them were the late model cars with their faired-in headlights.

The Lamborghini Gallardo is a sports car built by the Italian automotive manufacturer Lamborghini from 2003 to 2013. Named after a famous breed of fighting bull, the V10 powered Gallardo has been Lamborghini’s sales leader and stable-mate to a succession of V12 flagship models—first to the Murciélago (4,099 built between 2001 and 2010), then to the current flagship, the Aventador. The first generation of the Gallardo was powered with an even firing 4,961 cc (5.0 L) 90 degree V10 engine generating a maximum power output of 500 PS at 7500 rpm and 510 Nm (376 lb/ft) of torque at 4500 rpm. The Gallardo was offered with two choices of transmission; a conventional (H-pattern) six-speed manual transmission, and a six-speed electro-hydraulically actuated single-clutch automated manual transmission that Lamborghini called “E-gear”. The “E-gear” transmission provides gear changes more quickly than could be achieved through a manual shift. The driver shifts up and down via paddles behind the steering wheel, but can also change to an automatic mode via the gear selector located in place of the gear shift lever. The vehicle was designed by Luc Donckerwolke and was based on the 1995 Calà prototype designed by Italdesign Giugiaro. For the 2006 model year (launched in late 2005), Lamborghini introduced many changes to the car to counter some criticisms garnered from the press and owners. The exhaust system was changed to a more sporty one (including a flap to make it quieter during city driving), the suspension was revised, a new steering rack was fitted, the engine power was increased by 20 PS to a maximum of 520 PS and the biggest change was overall lower gearing ratios, especially in 1st to 5th gear. These changes gave the car a much better performance than the original and were also included in the limited edition Gallardo SE. The convertible variant of the Gallardo, called the Gallardo Spyder, was unveiled at the Los Angeles Auto Show in January 2006. It was considered by the company to be an entirely new model, with the engine having a power output of 520 PS (513 bhp) and a low-ratio six-speed manual transmission. The Spyder has a retractable soft-top. At the 2007 Geneva Auto Show, Lamborghini unveiled the Gallardo Superleggera. The name paid tribute to the construction style of the first Lamborghini production model, the 350 GT, designed and built by Carrozzeria Touring and its emphasis on weight reduction. The Superleggera is lighter than the base model by 100 kg (220 lb) due to the use of carbon fibre panels for the rear diffuser, undertray, the rearview-mirror housings, the interior door panels, the central tunnel, engine cover; titanium wheel nuts and carbon fibre sports seats. The engine power was uprated by 10 PS courtesy of an improved intake, exhaust and ECU for a total power output of 530 PS. The 6-speed E-Gear transmission was standard on US spec models with the 6-speed manual transmission offered as a no cost option. Production of the Superleggera amounted to 618 units worldwide. Presented at the 2008 Geneva Motor Show, the Gallardo LP 560-4 was a significant update of the Gallardo, powered by a new, uneven firing 5,200 cc V10 engine that produces 560 PS at 8,000 rpm and 540 Nm (398 lb/ft) of torque at 6,500 rpm. Featuring “Iniezione Diretta Stratificata” direct fuel injection system to improve efficiency; fuel consumption and CO2 emissions have been reduced by 18% despite the increase in performance. The car was redesigned, inspired by the Murciélago LP 640 and Reventón. The new engine, 40 PS more powerful than in the previous car, comes with two transmission choices: a 6-speed manual or 6-speed E-gear, the latter of which was revised to offer a Corsa mode which makes 40% quicker shifts than before and decreases traction control restrictions, a Thrust Mode launch control system was also added. Accompanied with a 20 kg (44 lb) weight reduction. All the improvements add up to a claimed performance of 0-100 km/h (62 mph) in 3.7 seconds, 0-200 km/h (124 mph) of 11.8 and a top speed of 325 km/h (202 mph). The MSRP base price was $198,000 in the US and £147,330 (including NavTrak vehicle tracking system and delivery package) in the UK. The first US car was sold in the 16th Annual Race to Erase MS charity auction for $198,000 to former True Religion Jeans co-founder/co-creator Kymberly Gold and music producer Victor Newman. The Lamborghini Gallardo LP 560-4 Spyder was unveiled at the 2008 LA Auto Show.as the replacement for the previous Gallardo Spyder. It is the convertible model of the Gallardo LP 560-4 and as such possess all of its features like the new uneven firing 5.2 L V10 engine, improved E-gear transmission and 20 kg (44 lb) weight reduction. Performance has been improved to 0-100 km/h (62 mph) in 3.8 seconds, 0-200 km/h (124 mph) of 13.1 and a top speed of 324 km/h (201 mph) In March 2010, Lamborghini announced the release of the Gallardo LP 570-4 Superleggera, a lightweight and more powerful version of the Gallardo LP 560–4 in the same vein as the previous Superleggera. With carbon fibre used extensively inside and out to reduce weight to just 1,340 kg (2,954 lb) making it the lightest road-going Lamborghini in the range. The odd firing 5.2 L V10 on the LP 570-4 gets a power bump over the standard Gallardo to 570 PS at 8,000 rpm and 540 Nm (398 lb/ft) at 6,500 rpm of torque. Performance has been improved to 0-100 km/h (62 mph) in 3.2 seconds, and a 329 km/h (204 mph) top speed. The Gallardo became Lamborghini’s best-selling model with 14,022 built throughout its production run. On 25 November 2013, the last Gallardo was rolled off the production line. The Gallardo was replaced by the Huracán in 2014

The Aventador has been a huge success for Lamborghini. It was first seen at the 2011 Geneva Show, with the full name of Aventador LP700-4 Coupe, the numbers denoting the output of 700 bhp from the all-new V12 engine and the 4 meaning four wheel drive, something which has featured on every Aventador since. The launch price was £250,000 but even so within a month, Lamborghini had a year’s worth of orders, and within a year, 1000 had been built. In November 2012 a Roadster version arrived, which was very similar to the Coupe, but with a lift-out roof panel. A suite of mechanical changes came at this point, with a cylinder deactiviation technology helping to improve fuel consumption and cut emissions. To mark half a century of car production, in April 2013, the LP720-4 50th Anniversary was launched, with 100 units available. As well as the extra 20 bhp, these had a mildly redesigned nose and tail, special paintwork and unique interior trim. A Roadster version followed in December 2014, the LP 700-4 Pirelli Edition. This did not have the extra power, but did feature two tone paint, unique wheels and a transparent engine cover, with the engine bay finished in carbon fibre. Lamborghini turned up the wick in March 2015 with the LP750-4 SuperVeloce, or SV for short, which featured and extra 50 bhp and a 50 kg weight reduction largely thanks to the use of more carbon fibre. A Roadster version followed a few months later.

The Aventador SVJ is the fastest Lamborghini you can buy new. With 759bhp and 531lb ft on tap, the SVJ (Superveloce Jota) matches the power output of the ultra-low-volume Centenario and is 29bhp more powerful than the Aventador S. This power figure is produced by a tuned version of Lamborghini’s naturally aspirated 6.5-litre V12 and is transmitted to the road through all four wheels. Four-wheel steering is also fitted, as per the Aventador S, but the SVJ builds upon the standard car’s agility with a second generation of its active aerodynamics system (ALA 2.0), with improvements over the first system including redesigned air inlets and aero channel designs. The system aided the SVJ in lapping the Nürburgring circuit in 6min 44.97sec – a new record for a production car. Lamborghini claims the SVJ’s downforce is 40% greater than that of the Aventador SV – its former performance flagship. Larger side air intakes, a huge rear wing, tweaked underbody with vortex generators and prominent rear diffuser and aerodynamic bodywork at the front help to achieve the improved aero figure. The chassis is tweaked for additional stiffness – a 50% stiffer anti-roll bar compared with the Aventador SV has been fitted, while the suspension’s damping force range is increased by 15% over the SV. Other tweaks to the suspension are claimed to improve the car’s on-track stability. A re-engineered exhaust system reduces back pressure and has been fettled to produce a “more emotive’ sound, as well as being lighter than the standard set-up, with higher exit points. Also among the mechanical upgrades is a tweaked seven-speed automated manual gearbox, while the four-wheel drive system now sends 3% more torque rearwards. The stability control and ABS systems are tweaked to accommodate the greater grip provided by the active aerodynamics. The car’s exclusive aluminium Nireo wheels are shod in specially made Pirelli P Zero Corsa tyres and are stiffer, with a bespoke tread design for the Aventador SVJ. Lamborghini plans to build 900 SVJs, with UK prices starting at around £356,000 when deliveries begin in early 2019. An additional 63 units will be produced in 63 Edition guise, of which the Pebble Beach reveal car is one, celebrating the brand’s 1963 inception. These feature a bespoke colour and trim and will carry a higher price tag than the regular SVJ.

The Lamborghini Huracán (Spanish for “hurricane”; [uɾaˈkan]) is a sports car replacing the previous V10 offering, the Gallardo. The Huracán was revealed online in December 2013, making its worldwide debut at the 2014 Geneva Auto Show, and was released in the market in the second quarter of 2014. The Huracán’s name (huracán being the Spanish word for hurricane) is inspired by a Spanish fighting bull. Historic Spanish fighting bulls have traditionally provided the names of most Lamborghini car models. Huracán was a bull known for its courage that fought in 1879. The Huracán maintains the 5.2-litre naturally aspirated Audi/Lamborghini V10 engine with an additional 0.2 litres, compared to the Gallardo, tuned to generate a maximum power output of 602 bhp/610 PS. To ensure its balance and performance, the car is mid-engined. The engine has both direct fuel injection and multi-point fuel injection. It combines the benefits of both of these systems; it is the first time this combination is used in a V10 engine. To increase its efficiency, the Huracán’s engine also includes a start-stop system. The firing order of the engine is 1, 6, 5, 10, 2, 7, 3, 8, 4, 9. This is printed on a metal plate on the top of the engine, as with all other Lamborghini models. The drag coefficient of Cd=0.39 was undisclosed until 2021. The LP 610-4 designation comes from the car having 610 PS and four-wheel drive, while LP stands for “Longitudinale Posteriore”, which refers to the longitudinal mid-rear engine position. Changes from the Gallardo include full LED illumination, a 12.3 inch full-colour TFT instrument panel, fine napa leather and Alcantara interior upholstery, redesigned dashboard and central tunnel, Iniezione Diretta Stratificata (IDS, essentially an adapted version of parent Audi’s Fuel Stratified Injection) direct and indirect gasoline injections, engine Stop & Start technology, EU6 emissions regulation compliance, Lamborghini Doppia Frizione (LDF) 7-speed dual-clutch transmission with 3 modes (STRADA, SPORT and CORSA), 20-inch wheels, carbon-ceramic braking system, optional Lamborghini Dynamic Steering variable steering system and MagneRide electromagnetic damper control. The main competitors of the Huracán include the McLaren 650S (as well as the 720S), the Audi R8, the Ferrari 458 Speciale and the 488 GTB. Extra options that increase the price of the car include interior enhancements, special paint schemes, improved suspension, and a lifting system, as well as multiple components optionally available in carbon fibre, rather than aluminium. The convertible variant of the Huracán LP 610-4 was revealed at the Frankfurt Motor Show on 14 September 2015. The 5.2-litre naturally-aspirated V10 engine is the same as the coupé and generates a maximum power output of 602 bhp/610 PS. Acceleration from 0 to 100 km/h (62 mph) takes 3.4 seconds and the top speed is 323 km/h (201 mph). It has the same 7-speed Lamborghini Doppia Frizione (LDF) dual-clutch transmission as that of the coupé. The Spyder has a dry weight of 1,542 kg (3,400 lb) which is 120 kg (265 lb) more than the coupé due to chassis reinforcing components. The Spyder has a CO2 emission of about 280 g/km. Unveiled at the 2016 Geneva Motor Show, the Huracán LP 580-2 is a lower cost derivative of the Huracán LP 610-4 that differs mostly in having the 5.2 L V10 engine detuned to 572 bhp/580 PS and 533 Nm (393 lb/ft) of torque along with having a rear wheel drive drivetrain instead of the all-wheel drive drivetrain found in the standard Huracán. Lamborghini claims the car will accelerate from 0–100 km/h (0–62 mph) in 3.4 seconds and 0–200 km/h (0–124 mph) in 10.1 seconds. The top speed is claimed to be as high as 320 km/h (199 mph). It also features slight visual differences to the standard variant of the car – with a different front fascia and larger air vents at the rear of the car for improved brake cooling. The seven-speed dual-clutch transmission is the same as used in the standard LP 610–4. The base level LP 580-2 costs US$201,100, about US$40,000 less than the base level LP 610–4. A convertible variant of the Huracán LP 580-2 was unveiled at the Los Angeles Auto Show on 16 November 2016. The 5.2-litre naturally-aspirated V10 engine is the same as in the coupé, and generates a maximum power output of 572 bhp/580 PS. 0 to 100 km/h (62 mph) takes 3.6 seconds and the top speed is 320 km/h (199 mph). A track oriented variant of the Huracán, called the Performante, was unveiled at the 2017 Geneva Motor Show. The Performante underwent various exterior changes with the most noticeable being the front and rear bumpers. Carbon fibre is used for the bumpers and the side skirts. An adjustable carbon fibre rear wing has been added to increase downforce. The position of the exhaust has also been changed, and is now just a bit above the rear diffuser. The interior also underwent noticeable changes, now sporting new seats and a new digital speedometer (similar to that of the Aventador SV’s speedometer). The Performante’s 5.2-litre V10 has been tuned to have a power output of 631 bhp/640 PS at 8,000 rpm and 601 Nm (443 lb/ft) of torque at 6,500 rpm. The weight has also decreased by 40 kg (88 lb), courtesy of the forged aluminium and forged carbon fibre body components (first used in the construction of the Sesto Elemento). All the new aero components on the car have active aerodynamic capability and help keep the car stable at high speeds. The Performante is capable of accelerating from 0–100 km/h (0–62 mph) in 2.9 seconds, 0–200 km/h (0–124 mph) in 8.9 seconds. It also has a theoretical top speed of 325 km/h (200 mph). The car has been stiffened by 10% with new springs, roll bars, and radial axial arm bushings. The magnetorheological suspension has been reworked to give a driver a serious track experience. The Lamborghini Dynamic Steering has been re-calibrated. The Performante utilises Lamborghini’s new ALA (Aerodinamica Lamborghini Attiva) system, which is said to be 80% lighter than regular sports car hydraulic systems. According to Lamborghini, ALA is also said to provide 750% more downforce than the standard Huracán. The Lamborghini Huracán Performante Spyder was unveiled at the 2018 Geneva Motor Show. It takes much of the styling inspiration from the coupé and the outgoing LP 610-4 Spyder. The Spyder is identical to the coupé from performance and technological standpoint, but the acceleration time from 0–60 mph has risen by one-tenth of a second and stands at 3.1 seconds while the 0–200 km/h (0–124 mph) has risen by four-tenths of a second and stands at 9.3 seconds. Due to the loss of the roof, the Spyder weighs 125 kg (276 lb) more than the coupé due to chassis reinforcing components. Top speed remains the same as well and stands at 325 km/h (202 mph). Deliveries of the Spyder began in the fourth quarter of 2018. The Huracán received a mid-cycle update in 2019, now being called the Huracán Evo. It now shares its engine and some of the technology with the Performante variant. The updated version of the Huracán has a more aggressive design language, the new front bumper has integrated aeroblades for improved downforce along with the rear styling inspired by the Performante variant, having the same rear diffuser, exhaust pipe position and radiators. A new ducktail spoiler improves downforce by 5 times as compared to the outgoing model. The engine is shared with the Performante and generates 631 bhp/640 PS at 8,000 rpm and 601 Nm (443 lb/ft) of torque at 6,500 rpm. The exhaust system is more refined and has titanium intake valves. This allows the car to achieve a 0–60 mph) acceleration time of 2.9 seconds, 0–200 km/h (0–124 mph) acceleration time of 9 seconds and a top speed of 325 km/h (202 mph). The car has a braking distance from 100–0 km/h (62–0 mph) of 104 ft (32 m). The Huracán Evo has a rear-wheel steering system for improved handling and a torque vectoring system. A new central processing unit controls the various functions of the car and monitors various settings. The control system is controlled by the new infotainment system (via an 8.4 inch touchscreen) dubbed the Lamborghini Dinamica Veicolo Integrata which has integrated both Apple CarPlay and Android Auto. The infotainment system predicts the driving modes by a feed forward logic. The feed forward logic works by sensors monitoring the lateral, longitudinal and vertical accelerations, as well as roll, pitch and yaw rate to predict the best possible driving mode for the driver. The magnetorheological suspension is also revised and now uses electromagnetic current to adjust the suspension system in accordance with the driving mode. The transmission system from the outgoing model is retained which transfers power to all four wheels. A new Ego mode allows the driver to change driving settings to their own preference. The Huracán Evo Spyder was introduced online in February 2019. The Spyder has the same enhancements as the coupé but is 100 kg (220 lb) heavier due to the addition of chassis reinforcement components owing to the loss of the roof. The car has the same canvas folding soft top as the outgoing model which takes 17 seconds for operation and is operable at speeds up to 50 km/h (31 mph). The Spyder can accelerate to 100 km/h (62 mph) in 3.1 seconds from a standstill, to 200 km/h (124 mph) in 9.3 seconds and can attain a top speed of 325 km/h (202 mph). A rear-wheel drive variant of the Evo debuted in January 2020, replacing the LP 580–2. The front splitter has been reshaped and generates more airflow, which is directed to the revised diffuser. Unique to the RWD model is P-TCS (Performance Traction Control System) that ensures that torque is not cut off abruptly; Lamborghini claims this increases oversteer by 30 percent compared to the LP 580–2. The engine is detuned and is now rated at 602 bhp/610 PS. Due to the detuned engine, the car is slower than the standard Huracán Evo accelerating to 100 km/h (62 mph) in 3.3 seconds while having the same top speed. The car also receives a unique paint option, Giallo Belenus, along with a matching interior upholstered in leather and microsuede. A convertible version of the rear-wheel drive variant of the Evo was showcased in May 2020, replacing the LP 580-2 Spyder. Like the Coupé variant, the convertible has a power output of 602 bhp/610 PS. The convertible has a 0– 60 mph acceleration time of 3.5 seconds and has a claimed top speed of 323 km/h (201 mph). Unveiled on April 12, 2022, The Huracán Tecnica sits between the EVO RWD and the track-focused STO. It is 6.1 cm (2.4 in) longer than the EVO, but is the same height and width. It uses the naturally-aspirated V10 engine from the STO and has a top speed of 325 km/h (202 mph) and an acceleration time of 0–100 km/h (0–62 mph) in 3.2 seconds. According to Lamborghini, the Tecnica’s aerodynamic changes increase downforce 35 percent and reduce drag by 20 percent compared to the EVO. It is expected that production will end in 2024.

 

The Huracán STO (Super Trofeo Omologato) is a track focused variant of the Huracan. It is completely different from other Huracan variants. The STO has a taller rear wing with a roof snorkel for engine cooling. There is a shark fin aerodynamic device connecting the roof snorkel with the rear wing. The engine cover is reminiscent of the Lamborghini Super Trofeo Evo race cars. The entire hood opens to reveal a small compartment for storing racing equipment, the body is made of 75% carbon fibre, the engine and the power output of the STO is the same as the Huracan Perfomante and the Huracan Evo but it has Rear-wheel drive with Rear Wheel Steering system, it has CCMR Brakes inspired from Formula 1. The STO comes with three new modes: STO for road driving, TROFEO for fast lap times on dry tarmac, and PIOGGIA for wet weather driving. The bucket seats on the interior feature racing harnesses.

The Lamborghini Urus is a high performance luxury SUV manufactured by Italian automobile manufacturer Lamborghini. It was introduced in December 2017 as a 2018 model year production vehicle. The Urus is the first Lamborghini SUV and five-door vehicle in the modern era (under the ownership of Volkswagen Group), and the second SUV in the brand’s history after the LM002, which was produced between 1986 and 1993. Built on the Volkswagen Group MLB Evo platform, the Urus shares many components with other Volkswagen Group luxury SUVs, such as the Audi Q7, Bentley Bentayga, Porsche Cayenne, and Volkswagen Touareg. With a top speed of 312 km/h (194 mph), the Urus SE is the fastest production SUV in the world. The name comes from the urus, the ancestor of modern domestic cattle, also known as the aurochs. The Lamborghini Urus concept was unveiled at the 2012 Beijing Auto Show on 23 April 2012. Later, the SUV was also shown at Pebble Beach in 2012. Powered by a 5.2-litre V10 engine shared with the Gallardo, the engine generated a theoretical maximum power output of 600 PS (592 bhp) and was accompanied with an all-wheel-drive system. The sharp-lined exterior design of the SUV takes heavy influence from the company’s V12 flagship, the Aventador. Previously, Lamborghini had trademarked the name “Urus” before the introduction of the Lamborghini Estoque at the 2008 Paris Motor Show, and automotive news blogs Jalopnik and Autoblog believed that the name would be applied to what was eventually found to be the Estoque. On 4 December 2017, the Urus was unveiled at Lamborghini’s Sant’Agata Bolognese headquarters, making it the brand’s first SUV since the LM002. The production version of the SUV received major changes to the exterior and featured a different powertrain than that of the concept. Production of the new Urus started at Lamborghini’s refreshed Sant’Agata facility, ahead of first deliveries in early 2018 with a targeted sales volume of around 3,500 a year. However, Lamborghini had to expand their factory in Sant’Agata Bolognese to meet the higher demand. In July 2020, the company announced the 10,000th unit of the Urus. In 2022, Lamborghini hit a major milestone by producing 20,000 of these SUVs, making the Urus the company’s best-selling model in the shortest time.

With UK deliveries having started recently, it was no surprise to see a couple of examples of the new Revuelto here.

LANCIA

A Bertone-designed concept car called the Lancia Stratos Zero was shown to the public in 1970, but shares little but the name and mid-engined layout with the Stratos HF version. A new car called the New Stratos was announced in 2010 which was heavily influenced by the design of the original Stratos, but was based on a Ferrari chassis and engine. Bertone had no previous business with Lancia, who were traditionally linked with Pininfarina, and he wanted to come into conversation with them. Bertone knew that Lancia was looking for a replacement for the ageing Fulvia for use in rally sports and so he designed an eye-catcher to show to Lancia. Bertone used the running gear of the Fulvia Coupé of one of his personal friends and built a running showpiece around it. When Bertone himself appeared at the Lancia factory gates with the Stratos Zero he passed underneath the barrier and got great applause from the Lancia workers. After that a co-operation between Lancia and Bertone was formed to develop a new rally car based on ideas of Bertone’s designer Marcello Gandini who already had designed the Lamborghini Miura and Countach. Lancia presented the Bertone-designed Lancia Stratos HF prototype at the 1971 Turin Motor Show, a year after the announcement of the Stratos Zero concept car. The prototype Stratos HF (Chassis 1240) was fluorescent red in colour and featured a distinctive crescent-shaped-wrap-around windshield providing maximum forward visibility with almost no rear visibility. The prototype had three different engines in its early development life: the Lancia Fulvia engine, the Lancia Beta engine and finally for the 1971 public announcement, the mid-mounted Dino Ferrari V6 producing 190 hp. The use of the Dino V6 was planned right from the beginning of the project, but Enzo Ferrari was reluctant to sign off the use of this engine in a car he saw as a competitor to his own Dino V6. After the production of the Dino car had ended the “Commendatore” (a popular nickname for Enzo Ferrari) agreed on delivering the engines for the Stratos, and Lancia then suddenly received 500 units. The Stratos was a very successful rally car during the 1970s and early 1980s. It started a new era in rallying as it was the first car designed from scratch for this kind of competition. The three leading men behind the entire rallying project were Lancia team manager Cesare Fiorio, British racer/engineer Mike Parkes and factory rally driver Sandro Munari with Bertone’s Designer Marcello Gandini taking a very personal interest in designing and producing the bodywork. Lancia did extensive testing with the Stratos and raced the car in several racing events where Group 5 prototypes were allowed during the 1972 and 1973 seasons. Production of the 500 cars required for homologation in Group 4 commenced in 1973 and the Stratos was homologated for the 1974 World Rally Championship season. The Ferrari Dino V6 engine was phased out in 1974, but 500 engines among the last built were delivered to Lancia. Production ended in 1975 when it was thought that only 492 were made (for the 1976 season, the Group 4 production requirement was reduced to 400 in 24 months. Manufacturer of the car was Bertone in Turin, with final assembly by Lancia at the Chivasso plant. Powered by the Dino 2.4 litreV6 engine that was also fitted to the rallying versions, but in a lower state of tune, it resulted in a power output of 190 hp, giving the road car a 0–100 km/h time of 6.8 seconds, and a top speed of 232 km/h (144 mph). The Stratos weighed between 900 and 950 kilograms, depending on configuration. Power output was around 275 hp for the original 12 valve version and 320 hp for the 24 valve version. Beginning with the 1978 season the 24 valve heads were banned from competition by a change to the FIA rules. Even with this perceived power deficit the Stratos was the car to beat in competition and when it did not suffer an accident or premature transmission failure (of the latter there were many) it had great chances to win. Despite the fact that the Stratos was never intended to be a race car, there were two Group 5 racing cars built with 560 hp, using a single KKK turbocharger. The car won the 1974, 1975 and 1976 championship titles in the hands of Sandro Munari and Björn Waldegård, and might have gone on to win more had not internal politics within the Fiat group placed rallying responsibility on the Fiat 131 Abarths. As well as victories on the 1975, 1976 and 1977 Monte Carlo Rally, all courtesy of Munari, the Stratos won the event with the private Chardonnet Team as late as 1979. Without support from Fiat, and despite new regulations that restricted engine power, the car would remain a serious competitor and proved able to beat works cars in several occasions when entered by an experienced private team with a talented driver. The last victory of the Stratos was in 1981, at the Tour de Corse Automobile, another World Rally Championship event, with a victory by longtime Stratos privateer Bernard Darniche. When the Fiat group favoured the Fiat 131 for rallying Lancia also built two Group 5 turbocharged ‘silhouette’ Stratos for closed-track endurance racing. These cars failed against the Porsche 935s on closed tracks but proved successful in hybrid events. While they failed in the Tour de France Automobile, one of these cars won the 1976 Giro d’Italia Automobilistico, an Italian counterpart of the Tour de France Automobile. One of the cars was destroyed in Zeltweg, when it caught fire due to overheating problems.  The last surviving car would win the Giro d’Italia event again before it was shipped to Japan to compete in the Fuji Speedway based Formula Silhouette series, which was never raced. The car would then be sold and reside in the Matsuda Collection before then being sold to the renowned collector of Stratos’, Christian Hrabalek, a car designer and the founder of Fenomenon Ltd, who has the largest Lancia Stratos Collection in the world, 11 unique Lancia Stratos cars, including the fluorescent red 1971 factory prototype and the 1977 Safari Rally car. His interest in the car led to the development of the Fenomenon Stratos in 2005. The Stratos also gained limited success in 24 Hours of Le Mans, with a car, driven by Christine Dacremont and Lella Lombardi, finishing 20th in 1976. Original cars are rare but there are lots of good quality recreations and replicas, such as the one seen here.

LOTUS

The original Elan was introduced in 1962 as a roadster, although an optional hardtop was offered in 1963 and a coupé version appeared in 1965, and there were examples of all of these here. The two-seat Lotus Elan replaced the elegant, but unreliable and expensive to produce Lotus Elite. It was the first Lotus road car to use a steel backbone chassis with a fibreglass body. At 1,600 lb (726 kg), the Elan embodied the Colin Chapman minimum weight design philosophy. Initial versions of the Elan were also available as a kit to be assembled by the customer. The Elan was technologically advanced with a DOHC 1557 cc engine, 4-wheel disc brakes, rack and pinion steering, and 4-wheel independent suspension. Gordon Murray, who designed the spectacular McLaren F1 supercar, reportedly said that his only disappointment with the McLaren F1 was that he couldn’t give it the perfect steering of the Lotus Elan. This generation of the two-seater Elan was famously driven by the character Emma Peel on the 1960s British television series The Avengers. The “Lotus TwinCam” engine was based on Ford Kent Pre-Crossflow 4-cylinder 1498 cc engine, with a Harry Mundy-designed 2 valve alloy chain-driven twin-cam head. The rights to this design was later purchased by Ford, who renamed it to “Lotus-Ford Twin Cam”. It would go on to be used in a number of Ford and Lotus production and racing models. Seen here was an example of the Drophead.

First mid-engined road-going Lotus was the Europa. The concept originated during 1963 with drawings by Ron Hickman, director of Lotus Engineering (Designer of the original Lotus Elan, as well as inventor of the Black and Decker Workmate), for a bid on the Ford GT40 project. That contract went to Lola Cars as Colin Chapman wanted to call the car a Lotus and Henry Ford II insisted it would be called Ford. Chapman chose to use Hickman’s aerodynamic design which had a drag coefficient of Cd 0.29 for the basis for the Europa production model. The car was originally intended to succeed the Lotus 7. Volkswagen owned the rights to the Europa name in Germany so cars for sale in Germany were badged Europe rather than Europa. The original Europa used Lotus founder Colin Chapman’s minimalist steel backbone chassis that was first used in the Lotus Elan, while also relying on its fibreglass moulded body for structural strength. The four-wheel independent suspension was typical of Chapman’s thinking. The rear suspension was a modified Chapman strut, as used for Chapman’s earlier Formula racing car designs. Owing to the rubber suspension bushes used to isolate engine vibration from the car body, the true Chapman strut’s use of the drive shaft as the lower locating link could not be followed whilst still giving the precise track and handling desired. The forward radius arms were increased in size and rigidity, to act as a semi-wishbone. A careful compromise between engine mounting bush isolation and handling was required, culminating eventually in a sandwich bush that was flexible against shear but stiff in compression and tension. The car’s handling prompted automotive writers to describe the Europa as the nearest thing to a Formula car for the road. Aside from the doors, bonnet, and boot, the body was moulded as a single unit of fibreglass. The first cars has Renault 1470cc engines, and suffered from a number of quality issues as well as limited visibility. An S2, released in 1968 brought improvements to the build quality, but Lotus knew that the Renault engine was not powerful enough for what they thought the car could achieve on track and on the road, so the Europa underwent another update in 1971 when the Type 74 Europa Twin Cam was made available to the public, with a 105 bhp 1557cc Lotus-Ford Twin Cam engine and a re-designed bodyshell to improve rearward visibility. Initially with the same gearbox as the earlier cars, once the supply had been exhausted in 1972 a new stronger Renault four-speed gearbox was introduced. Mike Kimberley, who rose to become chief executive of Group Lotus, then a new engineer at Lotus, was appointed Chief Engineer of the Europa TC project. 1,580 cars were shipped as Europa “Twin Cam” before Lotus switched to a 126 bhp “Big Valve” version of the engine. The big valve “Europa Special” version was aspirated by Dell’Orto carburettors version of the same engine; in addition it also offered a new Renault five-speed (Type 365) gearbox option. It weighed 740 kg (1631 lb), Motor magazine famously tested a UK Special to a top speed of 123 mph, did 0–60 mph in 6.6 seconds, and ran the 1/4 mile in 14.9 sec. This at a time when all road tests were carried out with both a driver and passenger, with only the driver on board the 0–60 mph time would have been well under 6 seconds, a phenomenal performance for the period. Introduced in September 1972 the first 100 big valve cars were badged and painted to honour the just won Team Lotus’ 1972 F1 World Championship title with John Player Special as sponsors, all with five-speed gearbox, these were all black with gold pin stripe matching the livery of the GP cars – plus a numbered JPS dash board badge, becoming the first ever John Player Special commemorative motor vehicles. The “Special” name and colour scheme was planned to be dropped after the first 200 cars, reverting to the Twin Cam name, but such was the reaction to the new car that the name and pin stripe scheme remained until the end of Europa Production although colours other than black were made available. In the end only the numbered plaque distinguishing the first 100 JPS cars from other black Europa Specials. According to Lotus sources, no Special left the factory with “numbered JPS badges” or “JPS stickers” – these were added by the American importer & weren’t official done by Lotus. There were no “badged” cars sold in the UK, Australia, etc, just in the USA. In total 4710 Type 74s were produced of which 3130 were “Specials”.

Perhaps my favourite of all the Lotus models on show were the early Esprit models. The silver Italdesign concept that eventually became the Esprit was unveiled at the Turin Motor Show in 1972 as a concept car, and was a development of a stretched Lotus Europa chassis. It was among the first of designer Giorgetto Giugiaro’s polygonal “folded paper” designs. Originally, the name Kiwi was proposed, but in keeping with the Lotus tradition of having all car model names start with the letter “E”, the name became Esprit. The production Esprit was launched in October 1975 at the Paris Auto Show, and went into production in June 1976, replacing the Europa in the Lotus model lineup. These first cars eventually became known as S1 Esprits. With a steel backbone chassis and a fibreglass body, the Esprit was powered by the Lotus 907 4-cylinder engine, as previously used in the Jensen Healey. This engine displaced 2.0 litre, produced 160 bhp in European trim 140 bhp in US/Federal trim, and was mounted longitudinally behind the passengers, as in its predecessor. The transaxle gearbox was a 5-speed manual unit, previously used in the Citroën SM and Maserati Merak; it featured inboard rear brakes, as was racing practice at the time. The Series 1 embodied Lotus’ performance through light weight mantra, weighing less than 1,000 kg (2,205 lb). The original Esprit was lauded for its handling and is said to have the best steering of any Esprit. However, it was generally regarded as lacking power, especially in markets such as the United States where the engine was down-rated for emissions purposes. Lotus’ claim of 0-60 mph in 6.8 seconds and a top speed of 138 mph may be thought of as optimistic – actual road test times indicated 0-60 mph in 8 seconds and a top speed of around 133 mph. The S1 Esprit can be distinguished from later Esprits by a shovel-style front air dam, Fiat X1/9 tail lights, lack of body-side ducting, and Wolfrace alloy wheels. Inside the car, the most obvious indication of an S1 Esprit is a one-piece instrument cluster with green-faced Veglia gauges. The car gained fame through its appearance in the James Bond film The Spy Who Loved Me (1977) where a fictionally-modified version was featured in a long action sequence. Bond’s Esprit car is first chased on road, by a motorcycle, then by another car, and then a helicopter, then converts into a submarine for an undersea battle. A series of improvements made to the Esprit during its initial run culminated in the S2 Esprit, which was introduced in 1978. The most obvious of these changes are intake and cooling duct “ears” located behind the rear quarter window, tail lights from the Rover SD1, and an integrated front spoiler. S2 Esprits also used 14-inch Speedline alloy wheels designed specifically for Lotus. Other changes included relocating the battery from above the right side fuel tank (under the rear quarter window) to the rear of the car, adding an access door to the engine cover, as well as replacing the instrument cluster made by Veglia with individual gauges made by Smiths and using different style of switches on the dashboard. During this era, a special edition car was released to commemorate Lotus’s racing victories and their victory in the 1978 F1 World Championship. Sharing the black and gold colour scheme of Lotus’ then F1 sponsor, John Player & Sons, these cars are commonly known as the John Player Special (JPS) Esprits. The “JPS” Esprit has the same mechanicals as the regular two-litre S2. According to Lotus themselves a limited series of 300 was built, but most likely the total was considerably lower.Lotus’ records of production figures are notoriously vague, but best estimates suggest that 149 JPS Esprits were produced. The S2.2 was produced as a stop-gap model from May 1980, almost identical to the S2 but with an enlarged (2.2 litre) type 912 engine used. This kept horsepower the same, but bumped up torque from 140 lb·ft to 160 lb·ft. Importantly, the S2.2 also introduced the use of a galvanised chassis, although it did not benefit from the succeeding S3’s chassis improvements. These cars are extremely rare even among Esprits: according to Lotus themselves, only 88 were produced in its thirteen-month production span. In 1980 the first factory turbocharged Esprit was launched. Initially, this was another special edition model commemorating F1 ties and reflecting current sponsorship, this time in the blue, red and chrome livery of Essex Petroleum, and is therefore known as the Essex Esprit. The new turbocharged dry-sump type 910 engine produced 210 hp and 200 lb·ft of torque. 0-60 mph could be achieved in 6.1 seconds, with a top speed of 150 mph. These performance improvements were coupled to a redesign and strengthening of the chassis and rear suspension, where an upper link was added to alleviate strain on the driveshafts, along with brake improvements. The Essex cars introduced a Giugiaro-designed aerodynamic body kit with a rear lip spoiler, prominent louvered rear hatch, more substantial bumpers, a deeper front airdam, and air ducts in the sills just ahead of the rear wheels, which were 15″ Compomotive three piece items. Internally, scarlet leather, combined with a roof-mounted Panasonic stereo, made for a dramatic environment. 45 Essex Esprits were built, interspersed and followed by a number of non Essex-liveried but otherwise identical specification dry-sump turbo cars. Two Essex-spec Turbo Esprits – one in white and the other in copper – were featured in the James Bond film For Your Eyes Only (1981), although these were scripted as the same vehicle – the white one was destroyed by an anti-burglar explosion system in Spain, while the copper red one was a “rebuild” of the original (actually a joke between Bond and Q in the latter’s laboratory), and was fully functional (the copper exterior paint colour for the replacement car was chosen to make the car stand out more in filming against the snowy background of Cortina, Italy, the only locale in which it appears). By the close of 1980, Lotus was effectively building three different models of Esprit, with distinct chassis designs and body moulds – the Domestic S2.2, the Export S2.2, and the dry-sump Turbo Esprit. Introduced in April 1981, the Turbo Esprit and S3 Esprits marked a necessary consolidation: both new models had a common chassis, inheriting much of the configuration of the Essex cars, whilst body production was based on a single common set of moulds. The S3 continued to use the 2.2 litre type 912 engine of the S2.2, whilst the Turbo Esprit reverted to a less complex wet-sump lubrication system, retaining the power and torque outputs of its dry-sump predecessor. The interior for both cars was revised and featured new trim; combined with changes to the body moulds this resulted in more headroom and an enlarged footwell. Externally, the Turbo Esprit retained the full aerodynamic body kit of the Essex cars, and featured prominent ‘turbo esprit’ decals on the nose and sides; the S3 gained the more substantial bumpers, yet retained the simpler sill line and glazed rear hatch of the S2.2 body style. Both models were supplied with 15″ BBS alloy wheels. For the 1985 model year, the S3 and Turbo underwent some slight alterations to the bodywork and to the front suspension. In April 1986, the final incarnations of the Giugiaro-styled Esprit were announced, with raised engine compression giving rise to the ‘HC’ moniker. This increased the output of the naturally aspirated engine to 172 hp and 160 lb·ft for the Esprit HC, and to 215 hp and 220 lb·ft for the Turbo Esprit HC, with the increased torque available at a lower rpm. For markets with stringent emissions requirements (mainly the United States), Lotus introduced the HCi variant, teaming the higher compression engine with Bosch KE-Jetronic fuel injection and a catalytic converter- the first fuel-injected Esprits. This engine had the same peak power as the carburettor version, but at a somewhat higher engine speed, and torque dropped to 202 lb/ft.

In 1987, a new version of the mid-engined Esprit was unveiled, incorporating rounder styling cues given by designer Peter Stevens (who later designed the McLaren F1). A new Lotus patented process was introduced to create the new body, called the VARI (Vacuum Assisted Resin Injection) process, which offered more advantages than the previous hand laid process. Kevlar reinforcement was added to the roof and sides for roll-over protection, resulting in an increase of the Esprit’s torsional rigidity by 22 percent. Giugiaro is said to have liked the restyling, claiming it was perhaps too close to his original design. The Stevens styled cars retained the mechanical components of the previous High Compression Esprit and Turbo Esprit, but introduced a stronger Renault transaxle, which necessitated a move to outboard rear brakes. However, the MY 1988 North American Esprit Turbo kept its Citroën SM type transaxle and the Bosch K-Jetronic fuel injection system used in the previous model year. The car’s Type 910 engine retained 215 bhp and 220 lb·ft, but decreased its zero to sixty from 5.6 seconds to a varied time between 5.4 – 5.1 seconds and a top speed of over 150 mph. The exterior style changes were accompanied by a redesign of the interior, allowing a little more space for the occupants. The Stevens styled Esprit is often known by its project code of X180. In 1989, the Esprit was again improved with the GM multi-port, electronic fuel injection system and the addition of a water to air intercooler, which Lotus has named the Chargecooler, producing the SE (Special Equipment). This inline-four engine was known as the Type 910S. Horsepower was pushed up to 264 with 280 available on overboost and zero to sixty miles per hour times reduced to 4.7 seconds with a top speed of over 160 mph. Several modifications were made to the body kit as well, like side skirts which are parallel to the body, five air ducts in the front air dam, wing mirrors from the Citroën CX and the addition of a rear wing. Along with the SE, Lotus produced the little seen Esprit S, a midrange turbocharged car offering fewer appointments and 228 hp, as well as the standard turbo still offering 215 hp . The N/A and lower-powered turbo were cancelled after 1990, and the S in 1991. Another unusual variant was a two-litre “tax special” developed for the Italian market, fitted with an intercooled and turbocharged version of a new 1,994 cc version of the venerable 900-series four-cylinder engine. Equipped with SE trim, this appeared in December 1991 and produced 243 PS at 6,250 rpm. Beginning in the autumn of 1996, this engine became available in other markets as well. The Esprit was a popular and successful addition to the American IMSA Bridgestone Supercar Championship and as a result Lotus produced the SE-based X180R, with horsepower bumped to 300 and with racing appointments. The Sport 300 was a derivative of the X180R sold in Europe, which included many modifications. These are known as the fastest of the four-cylinder Esprits and among the most desirable. In 1993, another exterior and interior revamp of the car resulted in the S4 which was the first model to include power steering. The exterior redesign was done by Julian Thompson, which included a smaller rear spoiler placed halfway up the rear decklid. Other major changes were to the front and rear bumpers, side skirts and valence panels. New five spoke alloy wheels were also included in the redesign. The S4 retained the same horsepower as the SE at 264 hp.The S4 was succeeded in 1994 by the S4s (S4 sport), which upped power to 300 bhp and 290 lb·ft of torque, improving all-around performance while retaining the comfort of the previous version. Top speed was increased to 168 mph, skidpad increased to 0.91g, an increased slalom of 61.7 mph and a 0-60 mph time of 4.6 seconds. Although the engine kept its 2.2-litre capacity, many modifications were added to improve engine performance. Some of the changes were enlarged inlet ports, cylinder head modifications, a re-calibrated ECM and a revised turbocharger. The most visible external styling changes was the addition of a larger rear wing taken from the Sport 300. In 1996 the Esprit V8 used Lotus’ self-developed all-aluminium, twin-turbocharged (Garrett T25/60 turbos) 90-degree V-8, Code-named Type 918, in front of the same Renault transmission as before with no Chargecooler. Derek Bell developed an uprated gearbox that overcame a lot of the gearbox problems with a much thicker single piece input shaft. The Type 918 engine was detuned from a potential 500 bhp to 350 bhp to prevent gearbox damage due to the fragility of the Renault UN-1 transmission. In period tests, zero to sixty miles per hour came in at 4.4 seconds and top speeds of over 175 mph were achieved. Produced alongside V8 models was the GT3, a turbocharged four-cylinder car with the type 920 2.0 litre chargecooled and turbocharged engine which had been used only in Italian market cars previously. In 1998 the V8 range was split into SE and GT specifications, both cars with a much changed interior configuration, both offering similar performance with the SE being the more luxurious of the two. The ultimate incarnation of the Esprit came in 1999 with the Sport 350. Only 50 were made, each offering 350 horsepower (per the name) and various engine, chassis and braking improvements, like the addition of AP Racing brakes, stiffer springs and a revised ECU. Several visual changes were made as well, including the addition of a large carbon fibre rear wing on aluminium uprights in place of the standard fibreglass rear wing. By this time the Esprit could reach 60 mph in 4.3 seconds as well as reaching 0-100 mph in less than 10 seconds, and weighed 1,300 kg (2,866 lb) as a result of many modifications. Thereafter, Lotus made little development aside from minor cosmetic changes including a switch to four round tail lights for the 2002 model year. Esprit production ceased in February 2004 after a 28 year production run. A total of 10,675 Esprits were produced.

It is now over 20 years since Lotus launched the Elise, a model which showed a return to the core values of simplicity and light-weight which were cornerstones of Colin Chapman’s philosophy when he founded the marque in 1955. The first generation Elise was produced for just over 4 years, with a replacement model, the Series 2 arriving in October 2000. It came about as the Series 1 could not be produced beyond the 2000 model production year due to new European crash sustainability regulations. Lacking the funding to produce a replacement, Lotus needed a development partner to take a share of investment required for the new car. General Motors offered to fund the project, in return for a badged and GM-engined version of the car for their European brands, Opel and Vauxhall. The result was therefore two cars, which although looking quite different, shared much under the skin: a Series 2 Elise and the Vauxhall VX220 and Opel Speedster duo. The Series 2 Elise was a redesigned Series 1 using a slightly modified version of the Series 1 chassis to meet the new regulations, and the same K-series engine with a brand new Lotus-developed ECU. The design of the body paid homage to the earlier M250 concept, and was the first Lotus to be designed by computer. Both the Series 2 Elise and the Opel Speedster/Vauxhall VX220 were built on the same production line, in a new facility at Hethel. Both cars shared many parts, including the chassis, although they had different drive-trains and power-plants. The VX220 carried the Lotus internal model identification Lotus 116, with the code name Skipton for the launch 2.2 normally aspirated version and Tornado for the 2 litre Turbo which came out in 2004. Fitted with 17 inch over the Elise’s 16 inch front wheels, the Vauxhall/Opel version ceased production in late 2005 and was replaced by the Opel GT for February 2007, with no RHD version for the United Kingdom. The Elise lived on. and indeed is still in production now, some 15 years later, though there have been countless different versions produced in that time. Whilst the first of the Series 2 cars came with the Rover K-Series engine, and that included the 111S model which had the VVC engine technology producing 160 hp, a change came about in 2005 when Lotus started to use Toyota engines. This was initially due to Lotus’ plans to introduce the Elise to the US market, meaning that an engine was needed which would comply with US emissions regulations. The selected 1.8 litre (and later 1.6 litre) Toyota units did, and the K-series did not. that MG-Rover went out of business in 2005 and engine production ceased confirmed the need for the change. Since then, Lotus have offered us track focused Elise models like the 135R and Sport 190, with 135 bhp and 192 bhp respectively, as well as the 111R, the Sport Racer, the Elise S and Elise R. In 2008 an even more potent SC model, with 218 bhp thanks to a non-intercooled supercharger was added to the range. In February 2010, Lotus unveiled a facelifted version of the second generation Elise. The new headlights are now single units; triangular in shape they are somewhat larger than the earlier lights. The cheapest version in Europe now has a 1.6 litre engine to comply with Euro 5 emissions, with the same power output as the earlier 1.8 136bhp car. Lotus has been through some difficult times in recent years, but things are looking more optimistic again, with production numbers having risen significantly in the last couple of years, after a period when next to no cars were made.

In 2004, the Series 2 Exige was introduced. It features a naturally aspirated 1.8 L 16-valve DOHC Toyota/Yamaha engine that is rated at 190 bhp with the Toyota engine designation of 2ZZ-GE. Compared to the Series 2 Elise, it has a front splitter, a fibreglass hardtop roof with roof scoop, a rear engine cover, and rear spoiler. The sole purpose of these aerodynamic additions to the base Elise is to create more downforce (almost 45 kg (100 lb) of downforce at 161 km/h (100 mph) in the Exige versus 5.9 kg (13 lb) at 100 mph in the Elise). In February 2005, Lotus announced a limited production run of 50 Exiges, using the Toyota engine with a supercharger. This increased the power output to 243 bhp. These models were only available in yellow or black, representing the colours of Lotus Sport, and are badged 240R. They have a projected 0 – 60 mph time of 3.9 seconds and 0-161 km/h (100 mph) of 9.9 seconds, with a top speed of 249 km/h (155 mph). The North American Exige was unveiled at the Los Angeles Auto Show in January 2006. According to Lotus, the standard Exige Series 2 model weighs 2,016 lb (914 kg). In February 2006, Lotus announced the Exige S model which used a supercharged Toyota 2ZZ-GE engine rated at 220 bhp The S was also made available in North American markets as a 2007 model. According to Lotus, the Exige S model, weighing 2,057 lb (933 kg), has the following specifications: In 2008, the Exige S was replaced by the Exige S 240. Power output increased by 9% over the outgoing model to 240 bhp. The S 240 also received upgraded AP Racing brakes from the Exige Cup 240 and a larger roof scoop utilised by the Exige Cup 255. 0–60 mph times improved to 4.0 seconds. The S 240 base manufacturer suggested retail price was $65,690. The Exige S 260 produced an additional 7% power output over the S 240 resulting in 256 bhp. Even with a full fuel tank, extensive use of weight-saving materials such as carbon fiber reduced the vehicle’s gross weight to 916 kg (2,020 lb) compared to 942 kg (2,077 lb) in the S 240. It can accelerate from 0–60 mph in 4.0 seconds. After 2009, both the S 240 and S 260 received distinctively new and enlarged rear spoilers mounted to the rear clam instead of the motor bay cover. Countless limited edition models were produced, as well. A third generation car was launched in 2012.

Developed under the project name Project Eagle, this car was launched as the Evora on 22 July 2008 at the British International Motor Show. The Evora is based on the first all-new vehicle platform from Lotus Cars since the introduction of the Lotus Elise in 1995 (the Exige, introduced in 2000, and the 2006 Europa S are both derivatives of the Elise Evora was planned to be the first vehicle of three to be built on the same platform and was the first product of a five-year plan started in 2006 to expand the Lotus line-up beyond its track-specialised offerings, with the aim of making Evora a somewhat of a more practical road car that would appeal to the mainstream. As such it is a larger car than recent Lotus models Elise and its derivatives (Exige, Europa S, etc.), with an unladen weight of 1,383 kg (3,049 lb). It is currently the only Lotus model with a 2+2 configuration, although it is also offered in a two-seater configuration, referred to as the “Plus Zero” option. It is also the only 2+2 mid engined coupé on sale. The interior is larger to allow taller persons of 6’5″ to fit. The cooled boot behind the engine is large enough to fit a set of golf clubs, although Lotus Design Head Russell Carr denies that this was intentional. Lotus intends Evora to compete with different market sectors including the Porsche Cayman. The name “Evora” keeps the Lotus tradition of beginning model names with an “E”. The name is derived from the words evolution, vogue, and aura. and it of course sounds similar to Évora, which is the name of a Portuguese city and UNESCO World Heritage Site. Sales started in summer 2009, with an annual target of 2000 cars per year, with prices between £45,000 and just over £50,000. and in America from the beginning of 2010. The Evora received several accolades at its launch from the British motoring press, including: Britain’s Best Driver’s Car 2009 from Autocar and Car of the Year 2009, from Evo. Sales, however, were far from target, as the car was seen as too costly. A more powerful Evora S was launched in 2010 with a supercharged equipped 3.5-litre V6. A facelifted and more powerful Evora 400 model was unveiled at the 2015 Geneva Motor Show.

A third Series Elise was debuted in 2010 and the car has undergone almost constant enhancements ever since, with power outputs boosted considerably on the way. Revealed in November 2015, the Lotus Elise Sport and Sport 220 joined the two-seater sports car’s line-up, with the two models replacing the outgoing Elise and Elise S. The models mark a return for the ‘Sport’ name to a Lotus, with the badge last appearing on the Lotus Esprit. The two cars get a weight reduction of 10kg, with the Elise Sport now down to 866kg and the Sport 220 now 914kg. The reduced weight doesn’t improve performance but it does bring a marginal boost in claimed economy, with the Sport now managing 45.0mpg the Sport 220 improving to 37.5mpg. The changes are marginal enough that the CO2 emissions remain unchanged. Both cars also come with lightweight sports seats, which are available with optional tartan trim that harks back to the 1970s Esprit S1. Other visual upgrades and options include lightweight silver or black cast wheels, which are 16 inch at the front and 17 inch at the rear. Optional lightweight wheels can shave another 5kg off the car’s weight. A black rear diffuser is standard, along with a choice of 10 different colours. Other options include a hard roof, air conditioning, cruise control and an upgraded Clarion stereo system. The engines remained unchanged. The Sport comes with a 1.6-litre petrol engine with 134 bhp and 160 Nm (118 lb/ft) of torque. It can go 0-62mph in 6.5 seconds, and has a top speed of 127mph. The Sport 220’s 1.8-litre engine can develop 217 bhp (220 PS) and 250 Nm (184 lb/ft) of torque. It can go 0-62mph in 4.6 seconds and has a 145mph of top speed. Both come with a six-speed manual transmission. The pricing has also been trimmed, with the Elise Sport model starting at £29,900 and the Elise Sport 220 priced at £36,500. Both cars will go on sale from December 2015 in Europe and the rest of the world from January 2016. At the 2016 Geneva Motor Show, Lotus revealed the high performance version of the Elise called the Cup 250. The Cup 250 is a more track focused and hardcore version of the standard Elise. It has a 1.8 litre supercharged Toyota 2ZR-FE Inline-4 engine with a 6-speed Toyota EC60 manual gearbox with sport ratios, developing 243 bhp at 7200 rpm, giving a 0-60 mph time of 3.9 seconds and a Top speed of 154 mph. In October 2017, Lotus unveiled a hardcore version of the Elise called the Elise Cup 260. It is inspired by the two hardcore variants of the Evora and Exige line up, the Sport 380 and the GT430 respectively. It features the double taillight units and rear wing from the Exige Sport 380 and the Lotus 3-Eleven respectively. Power has also been uprated and is now 250 hp thanks to a revised supercharger. Other changes include increased top speed, acceleration, low weight and high downforce due to added aero elements. Performance was marginally improved over the 220 version. In March 2017, Lotus announced the special edition ‘Sprint’ models of the Elise. For the Elise Sprint, Lotus used several weight-saving techniques to cut the car’s weight down to 798 kg (1,759 lb). To achieve the 40 kg (88 lb) weight saving, some body parts are made in carbon, as well as the seats. The backlight glass is made of polycarbonate, and the lightweight battery is a Lithium-ion model. Wheels are the usual size, but forged instead of cast alloy. The Sprint can be had with either a 1.6-litre naturally aspirated engine, or a 1.8-litre supercharged engine, available for the Sprint 220 version. The former has a 0–60 mph of 5.9 seconds, while the Sprint 220 can accelerate from 0–60 mph in 4.1 seconds. Dampers are uprated, as on the Elise Cup models. On 9 February 2021, Lotus unveiled two final editions line-up models of Elise on online platforms. Opening the range is the Elise Sport 240 Final Edition, which sees the existing Sport 220’s 1.8-litre supercharged four-cylinder engine uprated to develop 240 bhp and 244 Nm (180 lb/ft), permitting a zero to 100km/h time of 4.5 seconds. When fully specified with weight-saving options – namely carbon-fibre sill and engine covers, a lithium-ion starter battery and a polycarbonate rear window – the Sport 240 is the lightest car on offer, tipping the scales in at just 898kg. A set of 10-spoke forged alloy wheels fill the arches, measuring 16 inches in diameter up front and 17 inches at the rear, wrapped in Yokohama Y105 tyres. Lotus claims the new wheels are 0.5kg lighter than the examples fitted to the outgoing Sport 220. The Elise Cup 250 Final Edition features a variant of the Sport 240’s 1.8-litre four-cylinder, now tuned to produce 245 bhp and 244 Nm (180 lb/ft). Lotus claims a 4.3-second 0-100km/h sprint time. This model gets an optimised aerodynamic package allowing for 155kg of downforce at its top speed of 248km/h, along with 10-spoke M Sport forged alloy wheels, Yokohama A052 tyres, Bilstein dampers and adjustable anti-roll bars. A lightweight lithium-ion battery and polycarbonate rear window are also fitted as standard for increased weight saving, and, in top spec layout, the car weighs 931kg. The Elise story came to an end in late 2021 when production  of the model ceased after 25 years.

At the Frankfurt 2011 Show, the 2012 version of the Exige S was announced. It features a supercharged 3.5 litre V6 engine (from the Evora S) rated at 345 hp. In 2013, a roadster version was introduced with only minor changes to the design for the removable top. The engine and performance were virtually unchanged from the coupe. To accommodate the V6 engine, the new model is approximately 25 cm (9.8 inches) longer and 5 cm (2.0 in) wider (exterior bodywise) than the model with the inline-four engine, being 4,052 mm (159.5 inches) long, 1,802 mm (70.9 in) wide (not counting the mirrors) and 1,153 mm (45.4 in) tall. The drag coefficient is 0.433. Since that time there have been a bewildering array of different versions and you need to be a real marque expert to tell them all apart. The policy has worked, though, as sales have remained steady whilst Lotus try to amass the finances to develop any all new models. The Exige V6 Cup is a track oriented version of the Exige S while the Exige CupR is the track-only version of Exige V6 Cup. The Exige V6 Cup is offered for sale in the United States as a track only car. If purchased, US Lotus Dealers will only provide a bill of sale instead of a title. The vehicles were unveiled at the 2013 Autosport International motor show. Limited to 50 examples, the Lotus Exige 360 Cup was revealed on 14 August 2015. The car is powered by a 3.5-liter supercharged Toyota V6 delivering 355 hp. The Lotus Exige Sport 380 is a track focused and more powerful version of the Lotus Exige lineup. It was unveiled on 23 November 2016. Lotus’ CEO, Jean-Marc Gales describes it as, “The Exige Sport 380 is so good, that it is no longer the best in class, it’s now in a class of its own”, and it fulfills this statement by taking on some of the powerful and expensive super cars both on the track and the streets. The 3.5-litre, super-charged V6 engine is now uprated and produces 375 hp and 410 Nm (302 lb/ft) of torque with a 6500 rpm red line achieved by revised supercharger and ECU. It can accelerate from 0 to 60 mph in 3.5 seconds and has a top speed of 178 mph (286 km/h). The interior is also stripped out and features necessary driver aids. The Exige Sport 380 weighs 1,076 kg (2,372 lb), thanks to the extensive use of carbon fibre on the exterior as well as the interior, the application of polycarbonate windows instead of traditional glass windows and a newly designed rear transom panel which features two rear lights instead of four.The Lotus Exige Cup 380 is a more hardcore variant of the Exige Sport 380. Performance of the car remains the same as the Sport 380 but it features more aero components and a larger rear wing to produce more downforce at high speeds. The Exige Cup 380 generates 200 kg (441 lb) of downforce at its maximum speed of 175 mph (282 km/h); the top speed is reduced due to excess downforce and more drag. It features a more stripped out interior in order to save weight and other light weight carbon fiber components, Lotus states a lowest possible dry weight of only 1,057 kg (2,330 lb). On 9 November 2017, Lotus unveiled the most powerful version of the Exige to date called the Exige Cup 430, producing 430 PS (424 hp) and using the Evora GT430’s powertrain, modified to fit in the smaller Exige. The car body can produce 220 kg (485 lb) of downforce. The Cup 430 is 19 kg (42 lb) lighter than the Sport 380 due to the use of carbon fibre in body panels and interior and a titanium exhaust. The gearbox allows quicker gearshifts than the previous model. The Cup 430 is not offered with an automatic gearbox. The Lotus Exige Cup 430 is capable of covering the Hethel circuit in 1 minute 24.8 seconds – the fastest production car to lap the circuit – 1.2 seconds faster than the road going Lotus 3-Eleven.

Also here were a number of examples of the current sports car, the Emira an the recently released all-electric SUV, the Eletre.

MASERATI

Perhaps the highlight of the event was the display put on by Maserati GB with a special feature being a celebration of 60 years of the Quattroporte. There were examples of all six generations here, including the super rare second generation car.

The original Maserati Quattroporte (Tipo AM107) was built between 1963 and 1969. It was a large saloon powered by V8 engines—both firsts for a series production Maserati. The task of styling the Quattroporte was given to Turinese coachbuilder Pietro Frua, who drew inspiration from a special Maserati 5000 GT (chassis number 103.060) he had designed in 1962 for Prince Karim Aga Khan. While the design was by Frua, body construction was carried out by Vignale. The Quattroporte was introduced at the October-November 1963 Turin Motor Show, where a pre-production prototype was on the Maserati stand next to the Mistral coupé. Regular production began in 1964. The Tipo 107 Quattroporte joined two other grand tourers, the Facel Vega and the Lagonda Rapide, capable of travelling at 200 km/h (124 mph) on the new motorways in Europe. It was equipped with a 4.1-litre V8 engine, producing 260 hp at 5,000 rpm, and either a five-speed ZF manual transmission or a three-speed Borg Warner automatic on request. Maserati claimed a top speed of 230 km/h (143 mph). The car was also exported to the United States, where federal regulations mandated twin round headlamps in place of the single rectangular ones found on European models. Between 1963 and 1966, 230 units were made. In 1966, Maserati revised the Tipo 107, adding the twin headlights already used on the U.S. model. A leaf-sprung solid axle took place of the previous De Dion tube. The interior was completely redesigned, including the dashboard which now had a full width wood-trimmed fascia. In 1968 alongside the 4.1-litre a 4.7-litre version became also available (AM107/4700), developing 286 bhp. Top speed increased to a claimed 255 km/h (158 mph), making the Quattroporte 4700 the fastest four-door sedan in the world at the time. Around 500 of the second series were made, for a total of 776 Tipo 107 Quattroportes. Production ended in 1969.

The second generation Quattroporte, named Maserati Quattroporte II (AM 123), was introduced at the Paris Motor Show and the Turin Motor Show in October 1974. As the result of Citroën’s joint-venture with Maserati in 1968, the Quattroporte II was very different from its predecessor and the other Maserati automobiles of the past. Based on a stretched version of the Citroën SM’s chassis, the Quattroporte II featured a front-mid-engine, front-wheel-drive layout, hydropneumatic suspension, four fixed headlamps with two swivelling directional headlights, and a V6 engine. The bodywork was designed by Marcello Gandini at Bertone. Maserati had planned to equip Quattroporte II with a V8 engine, but the Tipo 107 V8 engine was too large for the Citroën SM based chassis on top of being too obsolete. A prototype for a 4.0-litre V8 engine was built from two compact Citroën-Maserati V6 engines. Maserati cut through the rear cylinders in half on one block (2.5 cylinders per bank, discarding the rear) and the middle cylinders in half on another block (1.5 cylinders per bank, discarding the front) then welded the blocks together. The output was 255 bhp. The new V8 engine was fitted to the Citroën SM for durability testing which lasted for 17,000 km (10,563 miles). This was done to prove that the chassis was robust enough to handle the additional power of the larger engine. Alejandro de Tomaso, the Italian entrepreneur who took over Maserati in 1975, cancelled the V8 engine programme. A single running prototype of the Quattroporte II was built and tested in 1974. The 1973 oil crisis and the collapse of Citroën’s finances in 1974 prevented Maserati from gaining the EEC approval for the European market. The production did not commence until 1976, and each Quattroporte II was built to order and sold in the Middle East and Spain where the type approval was not needed. Only twelve production cars were built from 1976 to 1978. The engineering and development had cost Maserati about four billion lire by the time the production ended in 1978.

The third generation car to bear the Quattroporte name (Tipo AM 330) was developed under the Alejandro de Tomaso-GEPI ownership. After the brief parenthesis of the Citroen-era front-wheel drive Quattroporte II, the third generation went back to the classic formula of rear-wheel drive and large Maserati V8 engine. It was designed by Giorgetto Giugiaro. A pre-production Quattroporte was introduced to the press by Maserati president Alejandro de Tomaso on 1 November 1976, in advance of its début at the Turin Motor Show later that month. It was only three years later though, in 1979, that the production version of the car went on sale. Initially “4porte” badging was used, changed in 1981 to Quattroporte. Two versions of the V8 engine were available: a 4,930 cc one producing 280 PS and a smaller 4,136 cc engine producing 255 PS which was phased out in 1981. The interior was upholstered in leather and trimmed in briar wood. The Quattroporte III marked the last of the hand-built Italian cars; all exterior joints and seams were filled to give a seamless appearance. From 1987 the Royale superseded the Quattroporte, as a built-to-order ultra-luxury version of the Quattroporte. It adopted a higher compression 4.9-litre engine, putting out 300 PS. Besides the usual leather upholstery and veneer trim, the passenger compartment featured a revised dashboard with analogue clock, four electrically adjustable seats, retractable veneered tables in the rear doors and a mini-bar. Visually the Royale was distinguished by new disc-shaped alloy wheels and silver-coloured side sills. De Tomaso announced a limited run of 120 Royales, but when production ceased in 1990 only 53 of them had been made. In all, including the Royale, 2,155 Quattroporte IIIs were produced.

Also here was the fourth generation Quattroporte, a model which was built from 1994 to 2001 on an evolved and stretched version of the Biturbo saloons’ architecture, which used twin-turbocharged V6 and V8 engines respectively from the Maserati Shamal and Ghibli coupés. For this reason the car retained very compact exterior dimensions, and is smaller than any of its predecessors and successors. As the designer’s signature angular rear wheel arches gave away, the wedge-shaped aerodynamic (0.31 Cd) body was the work of Marcello Gandini. The world première of the fourth generation Quattroporte took place at the April 1994 Turin Motor Show and the car went on sale towards the end of the year. Initially the Quattroporte was powered by twin-turbocharged, 24-valve V6 engines from the Maserati Ghibli. For export markets there was a 2.8-litre unit, producing 284 PS and reaching a claimed top speed of 255 km/h (158 mph). As local taxation strongly penalised cars over two-litre in displacement, Italian buyers were offered a 2.0 litre version, which developed a little more power (287 PS) but less torque than the 2.8; on the home market the 2.8 was not offered until a year after its introduction The cabin was fully upholstered in Connolly leather and trimmed in elm burr veneer. After having been displayed in December 1995 at the Bologna Motor Show, a 3.2-litre twin-turbocharged V8 Quattroporte was added to the range. Derived from the Maserati Shamal’s engine, on the Quattroporte this unit developed 336 PS for a claimed top speed of 270 km/h (168 mph). At the same time some minor updates were introduced on all models: new eight-spoke alloy wheels and aerodynamic wing mirrors, and seicilindri or ottocilindri (Italian for “six-” and “eight-cylinders” and) badges on the front wings, denoting which engine was under the bonnet. As standard all three engines were mated to a Getrag 6-speed gearbox, while 4-speed automatic transmissions were available on request with the 2.8 and 3.2 engines—respectively a 4HP22 by ZF and a computer-controlled one by Australian firm BTR. In July 1997 Ferrari acquired 50% of Maserati S.p.A. from Fiat S.p.A.. Ferrari immediately undertook a renewal of Maserati’s dated production facilities, as well as made improvements to the manufacturing methods and quality control. This resulted in the improved Quattroporte Evoluzione, introduced at the March 1998 Geneva Motor Show. It featured 400 all-new or modified parts out of a total 800 main components. Powertrains and performance remained unvaried, save for the adoption of the same BTR transmission from the 3.2 V8 by the automatic 2.8 V6 model. The Evoluzione no longer had the oval Maserati clock on the dashboard. Outside it was distinguished from the earlier models by details like “V6 evoluzione” or “V8 evoluzione” badges on the front wings and redesigned wing mirrors. Production of the fourth generation Quattroporte ended in May 2001.

Still acclaimed as one of the best-looking saloons ever produced is this car, the fifth generation Quattroporte, a number of which were on show. Around 25,000 of these cars were made between 2004 and 2012, making it the second best selling Maserati of all time, beaten only by the cheaper BiTurbo of the 1980s. The Tipo M139 was unveiled to the world at the Frankfurt Motor Show on 9 September 2003, with production starting in 2004. Exterior and interior design was done by Pininfarina, and the result was widely acclaimed to be one of the best looking saloons not just of its time, but ever, an opinion many would not disagree with even now. Built on an entirely new platform, it was 50 cm (19.7 in) longer than its predecessor and sat on a 40 cm (15.7 in) longer wheelbase. The same architecture would later underpin the GranTurismo and GranCabrio coupés and convertibles. Initially it was powered by an evolution of the naturally aspirated dry sump 4.2-litre V8 engine, mounted on the Maserati Coupé, with an improved output of 400 PS . Due to its greater weight compared to the Coupé and Spyder, the 0-62 mph (0–100 km/h) time for the Quattroporte was 5.2 seconds and the top speed 171 mph (275 km/h). Initially offered in only one configuration, equipped with the DuoSelect transmission, the gearbox was the weak point of the car, receiving most of the criticism from the press reviews. Maserati increased the range at the 2005 Frankfurt Motor Show, with the launch of the Executive GT and Sport GT trim levels. The Executive GT came equipped with a wood-rimmed steering wheel, an alcantara suede interior roof lining, ventilated, adaptive, massaging rear seats, rear air conditioning controls, veneered retractable rear tables, and curtain shades on the rear windows. The exterior was distinguished by 19 inch eight-spoke ball-polished wheels and chrome mesh front and side grilles. The Quattroporte Sport GT variant offered several performance upgrades: faster shifting transmission and firmer Skyhook suspensions thanks to new software calibrations, seven-spoke 20 inch wheels with low-profile tyres, cross-drilled brake rotors and braided brake lines. Model-specific exterior trim included dark mesh front and side grilles and red accents to the Trident badges, as on vintage racing Maseratis. Inside there were aluminium pedals, a sport steering wheel and carbon fibre in place of the standard wood inserts. A new automatic transmission was presented at the 2007 Detroit Motor Show, marketed as the Maserati Quattroporte Automatica.  As all three trim levels were offered in both DuoSelect and Automatica versions, the lineup grew to six models. The Quattroporte Sport GT S was introduced at the 2007 Frankfurt Motor Show. Taking further the Sport GT’s focus on handling, this version employed Bilstein single-rate dampers in place of the Skyhook adaptive system. Other changes from the Sport GT comprised a lowered ride height and 10 mm wider 295/30 rear tyres, front Brembo iron/aluminium dual-cast brake rotors and red-painted six piston callipers. The cabin was upholstered in mixed alcantara and leather, with carbon fibre accents; outside the door handles were painted in body colour, while the exterior trim, the 20 inch wheels and the exhaust pipes were finished in a “dark chrome” shade. After Images of a facelifted Quattroporte appeared on the Internet in January 2008; the car made its official début at the 2008 Geneva Motor Show. Overseen by Pininfarina, the facelift brought redesigned bumpers, side sills and side mirrors, a convex front grille with vertical bars instead of horizontal, new headlights and tail lights with directional bi-xenon main beams and LED turn signals. Inside there was a new navigation and entertainment system. All Quattroporte models now used the ZF automatic transmission, the DuoSelect being discontinued. The 4.2-litre Quattroporte now came equipped with single-rate damping comfort-tuned suspension and 18 inch wheels. Debuting alongside it was the Quattroporte S, powered by a wet-sump 4.7-litre V8, the same engine of the Maserati GranTurismo S, with a maximum power of 424 bhp and maximum torque of 361 lb·ft. In conjunction with the engine, the braking system was upgraded to cross-drilled discs on both axles and dual-cast 360 mm rotors with six piston callipers at the front. Skyhook active damping suspension and 19 inch V-spoke wheels were standard. Trim differences from the 4.2-litre cars were limited to a chrome instead of titanium-coloured front grille. The Quattroporte Sport GT S was premièred at the North American International Auto Show in January 2009. Its 4.7-litre V8 produced 440 PS (434 hp), ten more than the Quattroporte S, thanks to revised intake and to a sport exhaust system with electronically actuated bypass valves. Other mechanical changes were to the suspensions, where as on the first Sport GT S single-rate dampers took place of the Skyhook system, ride height was further lowered and stiffer springs were adopted. The exterior was distinguished by a specific front grille with convex vertical bars, black headlight bezels, red accents to the Trident badges, the absence of chrome window trim, body colour door handles and black double oval exhaust pipes instead of the four round ones found on other Quattroporte models. Inside veneers were replaced by “Titan Tex” composite material and the cabin was upholstered in mixed Alcantara and leather. This means that there are quite a number of different versions among the 25,256 units produced, with the early DuoSelect cars being the most numerous.

The most recent and sixth-generation of the Quattroporte was introduced in early 2013. With a 3,171 mm (124.8 in) wheelbase it is a considerably larger vehicle than any of its predecessors, to set itself apart from the smaller Ghibli, which shares its underpinnings. Engine choice includes twin-turbocharged V6 and V8 petrol engines, as well as a turbodiesel V6. Production ended in late 2023, with the last model year being 2024 and without successor.

Maserati had made their first forays into the grand tourer market, with the 1947 A6 1500, 1951 A6G 2000 and 1954 A6G/54, but whilst these cars had proven that the expanding the business beyond race cars was feasible; these A6 road cars were still built at the rate of just a dozen examples a year, which hardly constituted series production. A different approach was going to be needed, with the objective of building fully accomplished grand tourers. An engine was not really a problem. The 2 litre twin cam unit that had enabled Maserati to achieve racing success and international visibility in the early 1950s, thanks to cars such as the A6GCM;, had already been enlarged to three litre capacity on the Maserati 300S. Chief engineer Giulio Alfieri felt the next step was to design an all-new 3.5-litre engine; the resulting long-stroke six, designed foremost for endurance racing on the Maserati 350S, was ready in 1955. The main development efforts that led to the 3500 GT were carried out in 1956–57, despite the frantic activity required by Maserati’s participation in the Formula 1 world championship. Alfieri modified the 350S’s engine to suit a touring car, such as switching to a wet sump oil system and changing the engine accessories. He also made several business trips to the United Kingdom in order to contact components suppliers. None were found in Italy, as Italian taxation system and the industry structure forced manufacturers to design every part in-house; a daunting task for small companies like Maserati. Thus the 3500 GT alongside Italian Weber carburettors and Marelli ignition, used many British-made components such as a Salisbury rear axle, Girling brakes and Alford & Alder suspension parts. Clearly the bodywork would have to be Italian. According to Carrozzeria Touring’s Carlo Felice Bianchi Anderloni it was Commendatore Franco Cornacchia, a prominent Ferrari dealer, that put in contact Maserati owner Omar Orsi with the Milanese Carrozzeria The first 3500 GT Touring prototype had a 2+2 body, with superleggera construction and was white in colour; it was nicknamed Dama Bianca (White Lady). Two 3500 GT prototypes were shown at the March 1957 Salon International de l’Auto in Geneva. Both had a 2,600 mm (102.4 in) wheelbase and aluminium bodywork; they were Touring’s Dama Bianca, and another one by Carrozzeria Allemano. Touring’s proposal was chosen for series production; few changes were made to it, chiefly a more imposing grille. Production of the 3500 GT started in late 1957; eighteen cars were built that year, the first handful leaving the factory before Christmas. All 3500 GTs had leather interior and Jaeger-LeCoultre instruments. A first Touring convertible prototype was shown at the 1958 Turin Motor Show, but it was a proposal by Carrozzeria Vignale (designed by Michelotti) shown at the 1959 Salon de l’Auto in Paris that went into production as 3500 GT Convertibile. The Convertibile did not feature Touring’s Superleggera construction, but rather a steel body with aluminium bonnet, boot lid and optional hard top; it was also built on an 10 cm (3.9 in) shorter wheelbase, and weighed 1,380 kg (3,042 lb). Front disc brakes and limited slip differential became optional in 1959, and were standardised in 1960; rear discs became standard in 1962. The 3500 GTi was introduced at the 1960 Salon International de l’Auto, and by the following year became the first fuel-injected Italian production car. It had a Lucas mechanical fuel injection, and developed 232 bhp. A 5-speed gearbox was now standard. The body had a lowered roofline and became somewhat longer; minor outward changes appeared as well (new grille, rear lights, vent windows). From 1961 convertible 3500s for export markets were named 3500 GT Spyder and GTi Spyder. In total, 2,226 3500 GT coupés and convertibles were built between 1957 and 1964. In the first year, 1958, just 119 cars were sold, while 1961 was the best-selling year, totalling 500. All together, 245 Vignale convertibles and nearly 2000 coupés were manufactured, of these, 1981 being Touring coupés, the rest were bodied by other coachbuilders: Carrozzeria Allemano (four coupés, including the 1957 prototype), Zagato (one coupe, 1957), Carrozzeria Boneschi (1962 Turin Motor Show and 1963 Geneva Motor Show ), Pietro Frua (two or three coupés, one spider) and Bertone (one coupé, 1959 Turin Motor Show) The last was a coupé by Moretti for the 1966 Geneva Motor Show. The car was replaced by the Sebring in 1964.

Known internally as Tipo AM109, the Mistral was a 2-seat gran turismo produced between 1963 and 1970, as a successor to the 3500 GT. It was styled by Frua and bodied by Maggiora of Turin. Named after a cold northerly wind of southern France, it was the first in a series of classic Maseratis to be given the name of a wind. The Mistral was the last model from the Casa del Tridente (“House of the Trident”) to have the company’s renowned twin-spark, double overhead cam straight six engine. Fitted to the Maserati 250F Grand Prix cars, it won 8 Grand Prix between 1954 and 1960 and one F1 World Championship in 1957 driven by Juan Manuel Fangio. The engine featured hemispherical combustion chambers fed by a Lucas indirect fuel injection system, a new development for Italian car manufacturers. Maserati subsequently moved on to V8 engines for their later production cars to keep up with the demand for ever more powerful machines. Three engine were fitted to the Mistral, displacing 3500, 3700 and 4000 cc and developing 235 bhp at 5500 rpm, 245 bhp at 5500 rpm and 255 bhp at 5200 rpm, respectively. Only the earliest of the Mistrals were equipped with the 3500 cc, the most sought after derivative is the 4000 cc model. Unusually, the body was offered in both aluminium and, from 1967, in steel, but no one is quite sure how many of each were built. The car came as standard with a five speed ZF transmission and four wheel solid disc brakes. Per Maserati practice, the front suspension was independent and the rear solid axle. Acceleration 0-60 for both the 3.7 litre and 4.0 litre engines was around or just under 7 seconds, and top speed approximately 140 mph (225 km/h) to 145 mph (233 km/h). The body was designed by Pietro Frua and first shown in a preview at the Salone Internazionale dell’Automobile di Torino in November 1963. It is generally considered one of the most beautiful Maseratis of all time. It is also often confused with the very similar looking but larger and more powerful Frua designed AC 428. A total of 828 coupés and 125 Spyders were built. Only the Spyder received the 3500 engine; just 12 were made, along with 76 3.7 litre and 37 4.0 litre versions. Twenty Spyders were right hand drive. The Mistral was succeeded by the Ghibli, which overlapped production from 1967 on.

The Sebring was based on the earlier Maserati 3500 GT, and aimed at the American Gran Turismo market, taking its name from Maserati’s 1957 racing victory at the 12 Hours of Sebring. A single two-seat spyder was built by Vignale in 1963 but did not enter production. The Series I (Tipo AM 101/S) was shown at the Salon International de l’Auto 1962 and again at the Salone dell’automobile di Torino in 1963. Employing all but the Maserati 3500’s coachwork, it could reach 137 mph and 0–60 mph in 8.5 seconds on 185×15 Pirelli Cinturato tyres. A Borg-Warner automatic transmission was available, a first for Italian automobiles. When leaving the factory it originally fitted Pirelli Cinturato 205VR15 tyres (CN72). A total of 348 Series I Sebrings were built between 1962 and 1965. The engine was updated in 1963, gaining 15PS for a total of 235 PS. The 3700 engine first appeared in 1964, although only a handful of Series I cars were thus equipped. In 1965, the modified Series II (Tipo AM 101/10) was introduced. It had lightly redesigned headlamps, modernised bumpers, new front indicators, and new side grilles replacing the lower extraction vents used hitherto. It took minor design cues from the contemporary Quattroporte. At the rear, aside from the squared off bumpers, the taillights were now mounted horizontally rather than vertically and the bootlid opening was narrowed somewhat. The Series II rode on larger 205×15 Pirelli Cinturatos. A run of 247 units were made from 1964 until 1968. Along with the 3500 engine, the 3700 and the even larger 4000 were added. The 4000 GTiS has a 4,012 cc engine producing 255 PS at 5,200 rpm. It remained in production until 1968, when financial constraints forced Maserati to drop its older models from production. No major updates took place over the last three years of production, except for a slight power gain for the 4000, now up to 265 PS. 348 units of Sebring 3.5 and 245 of 3.7 and 4.0 (combined) were made, for a totalof 593 units from 1962 to 1969.

The Maserati Mexico’s design derived from a 2+2 prototype bodywork shown on the Vignale stand at the October 1965 Salone di Torino and built upon a 4.9-litre 5000 GT chassis, rebodied after it had been damaged. As the car after the show was sold to Mexican president Adolfo López Mateos, the model became known as the Mexico. By coincidence, John Surtees won the Mexican Grand Prix on a Cooper-Maserati T81 the following year. Vignale’s prototype was so well received that Maserati immediately made plans to put a version into production. The production Maserati Mexico debuted in August 1966 at the 20° Concorso internazionale di eleganza per auto in Rimini, while its international première was at the October Paris Motor Show. It was built on the first generation Quattroporte chassis with a wheelbase shortened by 11 cm (4.3 in). Originally powered by a 4.7-litre 90° V8 fed by four twin-choke 38 DCNL5 Weber carburettors that produced 290 bhp, the car managed to turn out a top speed between 240–250 km/h (149–155 mph). In 1969, however, contrary to Maserati tradition, the Mexico was also made available with a smaller engine, the 4.2-litre V8 engine. Apart from the smaller engine option the Mexico underwent few changes during its lifetime. Its luxurious interior included a rich leather seating for four adults, electric windows, wooden dashboard, iodine headlights and air conditioning as standard. Automatic transmission, power steering and a radio were available as optional extras. The 4.7-litre version was fitted with 650×15″ Borrani chrome wire wheels and the 4.2-litre version with steel disc wheels. When leaving the factory all Maserati Mexicos originally fitted Pirelli Cinturato 205VR15 tyres (CN72). The Mexico was the first production Maserati to be fitted with servo assisted ventilated disc brakes on all four wheels. In May 1967, under commission from the German concessionaire Auto Koenig for one client, Herr Rupertzhoven, Maserati built a ‘Mexico’ similar to Vignale’s original prototype design but was the work of Frua. Appearing like a 4-seat Mistral and built on the same tubular chassis as the 3500 GT (2600 mm wheelbase), this prototype ‘Mexico’ was fitted with the Mistral’s six-cylinder 3.7-litre Lucas fuel-injected engine. It was finished in Oro Longchamps with a black leather interior. Its dashboard came from the Quattroporte. 485 Mexicos were produced, 175 equipped with the 4.7 engine and 305 with the 4.2.

The Maserati Indy (Tipo AM 116) is a four-seater fastback grand tourer produced from 1969 to 1975. The Indy was conceived as an alternative to the Ghibli offering a V8 engine and room for four people; it effectively replaced both the ageing six-cylinder 2+2 Maserati Sebring—which descended from the 1957 3500 GT— and the first generation Quattroporte. Two coachbuilders showed their proposals at the November 1968 Salone dell’automobile di Torino, both based on a Maserati 4.2-litre chassis. On Ghia’s stand there was the Simùn, a 2+2 berlinetta designed by Giorgetto Giugiaro; on Carrozzeria Vignale’s, a sleek 4-seater fastback penned by Giovanni Michelotti. Both coachbuilders had already an established relationship with Maserati, as Vignale had been responsible for the 3500 GT Spyder, Mexico and Sebring, while Giugiaro had recently penned the Ghibli at Ghia. Vignale’s prototype was preferred, and the production model was launched by Maserati at the Geneva Motor Show the following March.  The car was christened Indy in honour of Maserati’s two victories at the Indy 500. At its launch in 1969 the Indy was offered with a 4.2-litre V8 engine. From 1970 a 4.7-litre Indy 4700 was offered alongside the 4200; the same year some interior updates were introduced, including seats with retractable headrests and a new dashboard. In 1972, Maserati added the Indy 4900 to the range, equipped with the new 4.9-litre V8. Production of the Indy ended in 1975. In total 1,104 were produced, 440 of them Indy 4.2s, 364 Indy 4.7s and 300 Indy 4.9s. These days the cars worth a fraction of the prices charged for a Ghibli, which makes them something of a bargain to my mind.

The Merak was the marque’s entry level car from the 1970s, introduced at the 1972 Paris Auto Show, over a year after the Bora, a car whose front part of the bodyshell up to the doors, it shares. The front ends are differenced mainly by the use of dual chrome bumpers in place of twin trapezoidal grilles, but the similarities end at the B-pillar. Unlike its bigger sister the Merak doesn’t have a true, fully glassed fastback, but rather a cabin ending abruptly with a vertical rear window and a flat, horizontal engine bonnet pierced by four series of ventilation slats. Giugiaro completed the vehicle’s silhouette by adding open flying buttresses, visually extending the roofline to the tail. The main competitors of the Merak were the similarly Italian, mid-engined, 3-litre and 2+2 Dino 308 GT4 and Lamborghini Urraco P250. However unlike its transverse V8-engined rivals the Merak used a more compact V6, that could therefore be mounted longitudinally. Having been designed during the Citroën ownership of Maserati, certain Citroën hydropneumatic systems were used in the Merak, as for the Bora. These included the braking system and the clutch which were both hydraulically assisted and operated, and the pop-up headlights were hydraulically actuated. After 1976, when the French manufacturer gave up cbontrol of Maserati, the Citroën-derived parts were gradually replaced by more conventional systems. In 1977 Alejandro de Tomaso purchased Maserati and the Bora was discontinued after a production run of less than 600 cars, while the Merak remained on sale for six more years. The Merak’s V6 engine descended from the 2.7 litre Tipo C.114 originally designed by Giulio Alfieri in 1967 for use in the Citroën SM, that was bored out to 91.6 mm to displace 2,965 cc. It was a chain-driven double overhead camshaft, 12-valve unit featuring an unusual 90° angle between the cylinder banks. The lubrication system used a wet sump and an oil cooler. This V6 did not end its days on the Merak: it was later modified and made into the first ever production twin-turbocharged engine in the Biturbo, ending its career in the 1990s Ghibli after reaching the highest specific output of any production engine at the time. The powerplant was mounted longitudinally behind the passenger compartment, and joined through a single-plate dry clutch to a 5-speed, all syncromesh Citroën transaxle gearbox and a limited-slip differential. The original Merak’s three-litre engine produced 190 PS at 6000 rpm. Three twin-choke Weber carburettors (one 42 DCNF 31 and two 42 DCNF 32) fed the engine, and the compression ratio was 8.75:1. Maserati declared a top speed of over 240 km/h (149 mph). Early Meraks (1972 to 1975) were fitted with the Citroën SM’s dashboard, characterised by oval instrument gauges inset in a brushed metal fascia and a single-spoke steering wheel. 630 were made up to 1974. The lightened and more powerful Merak SS (Tipo AM122/A) was introduced at the 41st Geneva Motor Show in March 1975, although it did not enter production until the next year. It featured a 50 kg weight reduction and a 30 PS power increase to 220 PS (217 hp), thanks to the adoption of three larger 44 DCNF 44 carburettors and a higher 9:1 compression ratio. The SS was recognisable from a black grille between the pop-up headlights. A Maserati-designed upper fascia with round instruments and a four-spoke steering wheel replaced the previous SM-derived interior furniture. Later cars were bestowed with the full driver-oriented dashboard and three-spoke padded steering wheel of the Maserati Bora. The US-spec version of the Merak SS also saw a return to traditional hydraulics, eliminating the last of the Citroen high pressure system. 1000 units of the SS had been made by 1983, when all Merak production ceased. A third version of the Merak was made, In November 1977 at the Turin Auto Show, De Tomaso launched the Merak 2000 GT (Tipo AM122/D), which was basically a Merak with a smaller two-litre powerplant. It was built almost exclusively for the Italian market, where a newly introduced law strongly penalised cars with engine capacity over 2000 cc by subjecting them to a 38% Value Added Tax against the usual 19% VAT. The Merak’s competitors already offered similar two-litre models, specifically the Urraco P200 and Dino 208 GT4. The Merak 2000 GT featured a 1,999 cc engine generating 170 PS (168 hp) at 7000 rpm. Colour choice was limited to two shades: metallic light blue or gold. The two-litre cars were also distinguished by a black tape stripe running just below the mid-body character line, matte black bumpers in place of the usual chrome and the absence of the front spoiler, available as an optional. The SS’s front bonnet with the grille between the headlights was used on 2000 GTs. When production ended in 1983 just 200 Meraks 2000 GT had been made. Although a total of 1830 Merak models were made, they are rare cars now. Their low values meant that when they went wrong, which they inevitably did, it was not economic to repair or restore them, and a large number have been scrapped, which is a pity, as this is a great looking car.

Top of the range throughout the 1970s was the stunning Khamsin and there was one of them here. Introduced on the Bertone stand at the November 1972 Turin Auto Show. and designed by Marcello Gandini, it was Bertone’s first work for Maserati. In March 1973 the production model was shown at the Paris Motor Show. Regular production of the vehicle started only a year later, in 1974. The Khamsin was developed under the Citroën ownership for the clientele that demanded a front-engined grand tourer on the lines of the previous Ghibli, more conventional than the mid-engined Bora. The Khamsin’s body is prominently wedge-shaped, with a fastback roofline and kammback rear end. The tail is characterized by a full-width glass rear panel, carrying inset “floating” tail lights. Combined with the wide, almost all-glass rear hatch this gave exceptional rear visibility in comparison to most cars, especially similar sports cars. Cosmetic triangular vented panels are inlaid in the C-pillar, with the right-hand one hiding the fuel filler cap. Another distinguishing feature is the engine bonnet, pierced by asymmetrical vents. Design features as the wedge body, glazed tail panel and the location of the fuel filler cap all carry Gandini’s signature, as they were all present on his earlier Lamborghini Espada. Despite being marketed as a 2+2, the leather-trimmed rear seats, nestled between the two fuel tanks, were found too lacking in headroom and legroom to be usable. The complete instrumentation included gauges for speedometer, tachometer, water temperature, oil temperature, oil pressure, voltmeter and a clock. The Khamsin used an all-steel monocoque construction, with a rear Silentbloc-bushing insulated tubular subframe supporting the rear suspension and differential. Suspension was double wishbones all around – a major improvement over the Ghibli’s leaf-sprung solid axle – with coaxial springs and shock absorbers (single upfront, double at the rear) and anti-roll bars. The front-mid mounted engine gave the car a 50/50 weight distribution; it was pushed so far back towards the firewall that the full size spare tyre could be stored beneath the radiator in front of it, thus freeing up space in the boot. Apart from the adoption of Bosch electronic ignition, Maserati’s 4,930 cc DOHC, 16-valve V8 engine was carried over from the Ghibli SS and delivered 320 bhp at 5500 rpm and 355.5 lb-ft of torque at 4000 rpm. It was fed through four double barrel 42 DCNF 41 Weber carburettors and used dry-sump lubrication. As on the Ghibli the fuel tanks were two, but not of similar size. A small tank is on the right and it is connected to the main tank below the cargo floor, with a single fuel filler on the right hand side feeding directly the small tank. The double exhaust system ended with two resonators, each with twin exhaust tips. Power was routed to the rear wheels through a 5-speed, all syncromesh ZF manual gearbox with a single-plate dry clutch; a 3-speed Borg Warner automatic transmission was also available on request. Khamsins rode on 215/70 Michelin XWX tyres on 7½J 15″ Campagnolo alloy wheels. Having been developed under the Citroën ownership, the Khamsin made large use of its high-pressure hydraulic systems. The power steering used the Citroën SM’s DIRAVI speed-sensitive variable assistance, which made steering lighter for easier parking and decreased its intervention with speed. The all-around vented disc brakes and the clutch command were both hydraulically actuated and assisted. The adjustable seats and the pop-up headlights were also hydraulically actuated. An adjustable steering column (an innovative feature at the time), air conditioning, electric windows, a radio and full leather upholstery were standard. Maserati claimed a 270 km/h (170 mph) top speed for the European-specification model. In 1977 a mild facelift added three horizontal slots on the Khamsin’s nose to aid cooling. Inside it brought a restyled dashboard and a new padded steering wheel. One Khamsin was delivered to Luciano Benetton in 1981. Despite the many improvements over its predecessor, the Khamsin didn’t replicate its success; partly due to the concurrent fuel crisis that decreased demand for big V8 grand tourers. Production ended in 1982, with 435 vehicles made (a mere third of the Ghibli’s 1274 examples production run) – 155 of whose had been exported to the United States.

Not a well known car these days, what was developed under the code of Tipo 129, the Kyalami is a four-seat GT coupé produced from 1976 to 1983. which was named after the Kyalami Grand Prix Circuit in South Africa, where a Maserati-powered Cooper T81 had won the 1967 South African Grand Prix. The Kyalami was the first new model developed under the Alejandro de Tomaso ownership. It was derived from, and mechanically virtually identical (except for some body panels) to the Longchamp, a three-box grand tourer made by De Tomaso Automobili. Pietro Frua was commissioned from De Tomaso to undertake the restyling of the Tom Tjaarda-designed Longchamp, to give the new car a distinctive Maserati feel. The interior was also upgraded to incorporate classic Maserati elements such the steering wheel and instrumentation. A Maserati four overhead camshaft 90° V8 was utilised to power the car, as opposed to the American-sourced Ford V8 which was used in the Longchamp. The Kyalami was launched at the 1976 Geneva Motor Show and was initially powered by a 265 PS 4.2-litre engine. Starting in 1978, an enlarged version of 4.9-litre displacement delivering 290 PS was also available. Both engines were coupled with a ZF five-speed manual transmission or upon request a three-speed Borg Warner automatic. Mechanically the Kyalami was closely related to its contemporary Quattroporte, which was also offered with the same engines and gearboxes. 210 Kyalamis were built between 1976 and 1983. Due to its rarity very little in the way of performance tests were published in the various international magazines when the car was new, and it features very seldom these days.

Maserati replaced their entire range in 1981 with the BiTurbo. Introduced initially as a single model, a 2 door coupe with a 2 litre twin-turbo V6 engine, over the next 15 years, it would evolve into a complex range of different models, and three basic bodystyles, as well as the special low-volume Karif and V8 engined Shamal cars. The car was designed by Pierangelo Andreani, Chief of Centro Stile Maserati up to 1981, and was somewhat influenced by the design of the recent Quattroporte III. The BiTurbo marked quite a change of direction for the Modense firm, a consequence of its acquisition by Alejandro de Tomaso in 1976. de Tomaso’s ambitious plans for the marque were to combine the prestige of the Maserati brand with a sports car that would be more affordable than the earlier high-priced models that had traditionally made up the Maserati range. The Biturbo was initially a strong seller and brought Italian prestige to a wide audience, with sales of about 40,000 units, but it quickly became apparent that the quality of the car was way off what the market expected, and the car is not regarded as one of the marque’s better models. Indeed, the Biturbo is number 28 in the BBC book of “Crap Cars” and in 2007 was selected as Time Magazine’s worst car of 1984, although they ranked the Chrysler TC by Maserati as a “greater ignominy”. Between 1987–89 a facelift was phased in, which helped to soften the sharp bodylines. The redesign included a taller and more rounded grille with mesh grille and bonnet, aerodynamic wing mirrors and 15″ disc-shaped alloy wheels, now mounted on 5-lug hubs. Some models received the wraparound bumpers with integral foglights and the deep sills introduced with the 2.24v. In 1991 the entire lineup was restyled for a second time, again by the hand of Marcello Gandini; the design features introduced with the Shamal were spread to the other models. Gandini, the Shamal’s designer, developed an aerodynamic kit that included a unique spoiler at the base of the windscreen hiding the windshield wipers, a rear spoiler, and side skirts. The new two-element headlights used poli-ellypsoidal projectors developed by Magneti-Marelli. Inset in body-colour housings, they flanked a redesigned grille, slimmer and integrated in the bonnet; the 1988 bumpers were adopted by all models. The 15″ disc-shaped alloys were replaced by new 16″ seven-spoke wheels, with a hubcap designed to look like a centerlock nut. The second facelift was referred to as “nuovolook”. The engines underwent change, too. As well as being the first ever production car with a twin-turbocharged engine, it was also the first production car engine with three valves per cylinder. The aluminium 90-degree SOHC V6 engine was roughly based on the 2.0 litre Merak engine, itself based on earlier V8 Formula One Maserati engines, designed by Giulio Alfieri. Because in Italy new cars with engine displacement over 2000 cc were subjected to a 38% value added tax, against 19% on smaller displacement cars, throughout the Biturbo’s production life there were both two-litre models aimed mainly at the domestic market and “export” versions, initially with a 2.5 litre V6. The carburettor 2.5 unit produced 185 hp and 208 lb·ft of torque in North American spec and slightly more elsewhere. Fuel injection was fitted in 1987 raising power to 187 hp. In 1989 the enlarged 2.8 litre engine bumped power to 225 hp and 246 lb·ft of torque for North America and 250 PS for Europe. In 1988, with the coupés being restyled, the Biturbo name was dropped in favour of 222—meaning 2-door, 2-litre engine and 2nd generation. The car carried all the visual clues of Gandini’s first facelift, with a more rounded grille and bonnet, different wing mirrors and rear spoiler. The engine size of the 222 E export model grew from the Biturbo’s 2.5- to 2.8-litres. A mixed velour-leather interior was standard on the domestic models, while export markets got leather upholstery as standard. 1990 saw the arrival of the 2.8 litre 222 SE, heir to the Biturbo ES. It inherited the latter’s limited paint finish availability (red, silver or black) and the dark trim and grille, while modern aprons and side skirts (blacked out as well) came from the 2.24v. After just a year the 222 SE was replaced by the 1991-restyled 222 SR; the SR offered adaptive suspension as an option. Simultaneously the very similar 222 4v. joined the lineup; it was a 222 SR with a 2.8 litre four-valve engine, the first DOHC car in the direct Biturbo E lineage. It used wider, 16″ 7-spoke wheels.

The Maserati Karif (Tipo AM339) is a luxury coupé produced by Italian automobile manufacturer Maserati between 1988 and 1991. It was designed to be luxurious, but also sporty and agile to allow the driver to “feel like a racing driver again or for the first time”. At the car’s unveiling, Alejandro de Tomaso declared a very limited production run of 250 examples. In the end, only 221 units were sold over the time the car was built. Production dates are not entirely clear, but the last cars were sold late in the summer of 1992, long after they had been built. In a throwback to Maserati’s earlier naming practices for two-seater GTs, the car was named after the wind called “Karif”, which blows South West across the Gulf of Aden at Berbera, Somalia. The Karif was built on the same shortened chassis as the Zagato-bodied Maserati Spyder model, adding a fixed notchback coupé roof. It used the powerful iteration of the Maserati Biturbo engine: the AM473, a 2.8  90° V6 engine with 3 valves per cylinder, rated at 285 PS at 5,500 rpm. According to Maserati, the Karif could accelerate to 100 km/h (62 mph) from a standstill in 4.8 seconds, and achieve a top speed of over 255 km/h (158 mph). Other sources claim power outputs of 248 PS, and 225 PS for the later catalysed model. With these lower power outputs, claimed top speeds were 233 and 230 km/h (145 and 143 mph) respectively. The rear limited-slip differential was a Ranger unit manufactured by GKN, while the 5-speed manual transmission was a ZF dog-leg unit.

In keeping with Maserati tradition, the Shamal was also named after a wind, in this case a hot summer wind that blows in large areas of Mesopotamia. My favourite of the Biturbo generation Maserati models, it was introduced on 14 December 1989 in Modena, when Maserati president and owner Alejandro de Tomaso showed it to the press, it was the last model announced under the De Tomaso ownership, as in January 1990 half of Maserati was acquired by Fiat S.p.A.. Sales began in 1990. The Shamal was designed by Marcello Gandini, of Bertone fame. Clearly based on the Biturbo, as you can see in the doors, interior, and basic bodyshell, all of which were carried over from the Biturbo. Gandini’s styling signature is visible in the slanted profile of the rear wheel wheel arch, also present on the fourth generation Quattroporte IV and first seen on the Lamborghini Countach. Nonetheless, the Shamal has a look all of its own, with the centre pillar wrapping around the cabin as a roll bar, always finished in black, a distinguishing characteristic of the Shamal. The name “Shamal” appears on either side of the central pillar in chrome lettering. The car has alloy wheels, a small rear spoiler and a blacked-out grille with chrome accents. Another defining feature of the Shamal are its numerous headlamps in individual housings: outer round Carello low beams of the then-new projector type, inner rectangular high beams, combined indicators and position lamps in the bumper, and two pairs of square lights in the lower grille—fog lamps and driving lamps. The two-seat interior of the Shamal features extended leather seat cushions, temperature control and the famous Maserati oval clock, which is situated in the centre of the dashboard. The gear lever is finished in elm. While built for comfort as well as performance, the Shamal was not as luxuriously appointed as the similar Maserati Ghibli II. The Shamal used a traditional front-engine, rear-wheel-drive layout and an all-steel unibody construction. Suspension was by MacPherson struts upfront and semi-trailing arms at the rear. All Shamals were equipped with an adaptive suspension developed by Maserati together with Koni. The system varied the damping rates, based on road conditions and the level of comfort desired. It was powered by an AM 479 3,217 cc square (bore and stroke 80 mm) V8 engine, with two overhead camshafts per bank, and four valves per cylinder. It was twin-turbocharged with two IHI turbines and intercoolers, and equipped with a Marelli IAW integrated electronic ignition and fuel injection ECU per cylinder bank. The engine put out 325 PS at 6,000 rpm and 320 lb·ft at 3,000 rpm. Power was sent to the rear wheels through a six-speed Getrag manual transmission and Maserati’s Ranger limited-slip differential. The manufacturer claimed a top speed of 170 mph and a 0 to 62 mph acceleration time of 5.3 seconds. The final year of production for the Maserati Shamal was 1996 and factory figures indicate that 369 examples were produced.

The Ghibli name was resurrected with the unveiling at the 62nd Turin Motor Show in April 1992. of the 1992 Ghibli (Tipo AM336). Like the V8 Maserati Shamal, it was an evolution of the previous Biturbo coupés; the doors, interior, and basic bodyshell were carried over from the Biturbo. It was powered by updated 24-valve Biturbo engines: a 2.0-litre V6 coupled to a six-speed manual transmission for the Italian market, and a 2.8-litre V6 for export, at first with a 5-speed manual, then from 1995 with the 6-speed. A 4-speed automatic was optional. The coupé was built for luxury as well as performance, and its interior featured Connolly leather upholstery and burl elm trim. At the 1994 Geneva Motor Show, Maserati launched an updated Ghibli. A refreshed interior, new wing mirrors, wider and larger 17″ alloy wheels of a new design, fully adjustable electronic suspension and ABS brakes were added. The Ghibli Open Cup single-make racing car was announced in late 1994. Two sport versions were introduced in 1995. The first was the Ghibli Kit Sportivo, whose namesake handling kit included wider tyres on OZ “Futura III” split-rim wheels, specific springs, dampers and anti-roll bars. The second was the limited edition Ghibli Cup, which brought some features of the Open Cup racer into a road-going model; it debuted at the December 1995 Bologna Motor Show. it mounted a 2-litre engine upgraded to 330 PS.  At the time the Ghibli Cup had the highest ever per litre power output of any street legal car, surpassing the Bugatti EB110 and Jaguar XJ220. Chassis upgrades included tweaked suspension and Brembo brakes. Visually the Cup was recognizable from its 5-spoke split-rim Speedline wheels and badges on the doors. Only four paint colours were available: red, white, yellow and French blue. The sporty theme continued in the Cup’s cabin with black leather, carbon fibre trim, aluminium pedals and a MOMO steering wheel. A second round of improvements resulted in the Ghibli GT in 1996. It was fitted with 7-spoked 17″ alloy wheels, black headlight housings, and had suspension and transmission modifications. On 4 November 1996 on the Lake Lugano, Guido Cappellini broke the flying kilometre’s World Speed Record on water in the 5-litre class piloting a composite-hulled speedboat powered by the biturbo V6 from the Ghibli Cup and run by Bruno Abbate’s Primatist/Special Team, at an average speed of 216,703 km/h. To celebrate the world record Maserati made 60 special edition Ghiblis called the Ghibli Primatist. The cars featured special Ultramarine blue paintwork and two-tone blue/turquoise leather interior trimmed in polished burr walnut. Production of the second generation Ghibli ended in summer 1998.

After producing BiTurbo based cars for 17 years, Maserati replaced their entire range with a new model in July 1998, the 3200 GT. This very elegant 2+2 grand tourer was styled by Italdesign, whose founder and head Giorgetto Giugiaro had previously designed, among others, the Ghibli, Bora and Merak. The interior design was commissioned to Enrico Fumia. Its name honoured the Maserati 3500 GT, the Trident’s first series production grand tourer. Sold mainly in Europe, the 3200 GT was powered by the twin-turbo, 32-valve, dual overhead cam 3.2-litre V8 engine featured in the Quattroporte Evoluzione, set up to develop 370 PS (365 hp). The car was praised for its styling, with the distinctive array of tail-lights, consisting of LEDs, arranged in the shape of boomerang being particularly worthy of comment. The outer layer of the ‘boomerang’ provided the brake light, with the inner layer providing the directional indicator. The car was also reviewed quite well by the press when they got to drive it in early 1999, though it was clear that they expected more power and excitement. That came after 4,795 cars had been produced, in 2001, with the launch of the 4200 models. Officially called the Coupé and joined by an open-topped Spyder (Tipo M138 in Maserati speak), these models had larger 4.2 litre engines and had been engineered so the cars could be sold in America, marking the return to that market for Maserati after an 11 year gap. There were some detailed styling changes, most notable of which were the replacement of the boomerang rear lights with conventional rectangular units. Few felt that this was an improvement. The cars proved popular, though, selling strongly up until 2007 when they were replaced by the next generation of Maserati. Minor changes were made to the model during its six year production, but more significant was the launch at the 2004 Geneva Show of the GranSport which sported aerodynamic body cladding, a chrome mesh grille, carbon fibre interior trim, and special 19-inch wheels. It used the Skyhook active suspension, with a 0.4 inch lower ride height, and the Cambiocorsa transmission recalibrated for quicker shifts. The exhaust was specially tuned to “growl” on start-up and full throttle. The GranSport was powered by the same 4244 cc, 90° V8 petrol engine used on the Coupé and Spyder, but developing 400 PS (395 hp) at 7000 rpm due primarily to a different exhaust system and improvements on the intake manifolds and valve seats. A six-speed paddle shift transmission came as standard. The GranSport has a claimed top speed of 180 mph (290 km/h) and a 0–62 mph (0–100 km/h) time of 4.8 seconds.

The Maserati GranTurismo and GranCabrio (Tipo M145) are a series of a grand tourers produced from 2007 to 2019. They succeeded the 2-door V8 grand tourers offered by the company, the Maserati Coupé, and Spyder. The GranTurismo set a record for the most quickly developed car in the auto industry, going from design to production stage in just nine months. The reason being that Ferrari, after selling off Maserati to the Fiat Chrysler Group, took the designs of the proposed replacement of the Maserati Coupé and after some modifications, launched it as the Ferrari California. Unveiled at the 2007 Geneva Motor Show, the GranTurismo has a drag coefficient of 0.33. The model was initially equipped with a 4.2-litre V8 engine developed in conjunction with Ferrari. The engine generates a maximum power output of 405 PS and is equipped with a 6-speed ZF automatic transmission. The 2+2 body was derived from the Maserati M139 platform, also shared with the Maserati Quattroporte V, with double-wishbone front suspension and a multilink rear suspension. The grand tourer emphasises comfort in harmony with speed and driver-enjoyment. The better equipped S variant was unveiled at the 2008 Geneva Motor Show and features the enlarged 4.7-litre V8 engine shared with the Alfa Romeo 8C Competizione, rated at 440 PS at 7,000 rpm and 490 Nm (361 lb/ft) of torque at 4,750 rpm. At the time of its introduction, it was the most powerful road-legal Maserati offered for sale (excluding the homologation special MC12). The engine is mated to the 6-speed automated manual shared with the Ferrari F430. With the transaxle layout weight distribution improved to 47% front and 53% rear. The standard suspension set-up is fixed-setting steel dampers, with the Skyhook adaptive suspension available as an option along with a new exhaust system, and upgraded Brembo brakes. The seats were also offered with various leather and Alcantara trim options. The upgrades were made to make the car more powerful and more appealing to the buyers while increasing performance, with acceleration from 0–100 km/h (0–62 mph) happening in 4.9 seconds and a maximum speed of 295 km/h (183 mph). Aside from the power upgrades, the car featured new side skirts, unique 20-inch wheels unavailable on the standard car, a small boot lip spoiler, and black headlight clusters in place of the original silver. The variant was available in the North American market only for MY2009 with only 300 units offered for sale. The GranTurismo MC is the racing version of the GranTurismo S developed to compete in the FIA GT4 European Cup and is based on the Maserati MC concept. The car included a 6-point racing harness, 120 litre fuel tank, 380 mm (15.0 in) front and 326 mm (12.8 in) rear brake discs with 6-piston calipers at the front and 4-piston calipers at the rear, 18-inch racing wheels with 305/645/18 front and 305/680/18 rear tyres, carbon fibre bodywork and lexan windows throughout along with a race interior. All the weight-saving measures lower the weight to about 3,000 lb (1,361 kg). The car shares the 4.7-litre V8 engine from the GranTurismo S but is tuned to generate a maximum power output of 450 PS along with the 6-speed automated manual transmission. The GranTurismo MC was unveiled at the Paul Ricard Circuit in France. It went on sale in October, 2009 through the Maserati Corse programme. 15 GranTurismo MC racecars were developed, homologated for the European Cup and National Endurance Series, one of which was taken to be raced by GT motorsport organization Cool Victory in Dubai in January, 2010. Introduced in 2008, the GranTurismo MC Sport Line is a customisation programme based on the GranTurismo MC concept. Changes include front and rear carbon-fibre spoilers, carbon-fibre mirror housings and door handles, 20-inch wheels, carbon-fibre interior (steering wheel rim, paddle shifters, instrument panel, dashboard, door panels), stiffer springs, shock absorbers and anti-roll bars with custom Maserati Stability Programme software and 10 mm (0.4 in) lower height than GranTurismo S. The programme was initially offered for the GranTurismo S only, with the product line expanded to all GranTurismo variants and eventually all Maserati vehicles in 2009. Replacing both the GranTurismo S and S Automatic, the Granturismo Sport was unveiled in March 2012 at the Geneva Motor Show. The revised 4.7L engine is rated at 460 PS. The Sport features a unique MC Stradale-inspired front fascia, new headlights and new, sportier steering wheel and seats. The ZF six-speed automatic gearbox is now standard, while the six-speed automated manual transaxle is available as an option. The latter has steering column-mounted paddle-shifters, a feature that’s optional with the automatic gearbox. New redesigned front bumper and air splitter lowers drag coefficient from Cd=0.33 to 0.32. In September 2010, Maserati announced plans to unveil a new version of the GranTurismo – the MC Stradale – at the 2010 Paris Motor Show. The strictly two-seat MC Stradale is more powerful than the GranTurismo at 450 PS, friction reduction accounts for the increase, says Maserati, due to the strategic use of “diamond-like coating”, an antifriction technology derived from Formula 1, on wear parts such as the cams and followers. It is also 110 kg lighter (1,670 kg dry weight) from the GranTurismo, and more aerodynamic than any previous GranTurismo model – all with the same fuel consumption as the regular GranTurismo. In addition to two air intakes in the bonnet, the MC Stradale also receives a new front splitter and rear air dam for better aerodynamics, downforce, and improved cooling of carbon-ceramic brakes and engine. The body modifications make the car 48 mm (2 in) longer. The MC Race Shift 6-speed robotised manual gearbox (which shares its electronics and some of its hardware from the Ferrari 599 GTO) usually operates in an “auto” mode, but the driver can switch this to ‘sport’ or ‘race’ (shifting happening in 60 milliseconds in ‘race’ mode), which affects gearbox operations, suspension, traction control, and even the sound of the engine. The MC Stradale is the first GranTurismo to break the 300 km/h (186 mph) barrier, with a claimed top speed of 303 km/h (188 mph). The push for the Maserati GranTurismo MC Stradale came from existing Maserati customers who wanted a road-legal super sports car that looked and felt like the GT4, GTD, and Trofeo race cars. It has been confirmed by the Maserati head office that only 497 units of 2-seater MC Stradales were built in total from 2011 to 2013 in the world, Europe: 225 units, China: 45 units, Hong Kong: 12, Taiwan: 23 units, Japan: 33 units, Oceania: 15 units and 144 units in other countries. US market MC’s do not have the “Stradale” part of the name, and they are sold with a fully automatic six-speed transmission rather than the one available in the rest of the world. US market cars also do not come with carbon fibre lightweight seats like the rest of the world. The MC Stradale’s suspension is 8% stiffer and the car rides slightly lower than the GranTurismo S following feedback from racing drivers who appreciated the better grip and intuitive driving feel of the lower profile. Pirelli has custom-designed extra-wide 20-inch P Zero Corsa tyres to fit new flow-formed alloy wheels. The Brembo braking system with carbon-ceramic discs weighs around 60% less than the traditional system with steel discs. The front is equipped with 380 x 34 mm ventilated discs, operated by a 6 piston caliper. The rear discs measure 360 x 32 mm with four-piston calipers. The stopping distance is 33 m at 100 km/h (62 mph) with an average deceleration of 1.2g. At the 2013 Geneva Motor Show, an update to the GranTurismo MC Stradale was unveiled. It features an updated 4.7 litre V8 engine rated at 460 PS at 7,000 rpm and 520 Nm (384 lb/ft) of torque at 4,750 rpm, as well as the MC Race Shift 6-speed robotized manual gearbox which shifts in 60 milliseconds in ‘race’ mode. The top speed is 303 km/h (188 mph). All models were built at the historic factory in viale Ciro Menotti in Modena. A total of 28,805 GranTurismos and 11,715 units of the convertible were produced. The final production example of the GranTurismo, called Zéda, was presented painted in a gradient of blue, black and white colours.

From the current range was the Levante, Maserati’s first SUV and the lauded MC20 supercar.

McLAREN

A heavily revised version of the MP12-4C was announced in February 2014, called the 650S, with revised bodywork, upgraded engine and other technical improvements. In April 2014, McLaren announced the end of production of the 12C. The 650S is the core model in the Super Series, designed and developed to give the enthusiast driver the ultimate in luxury, engagement and excitement. Fitted with the award-winning 3.8-litre twin turbo V8 engine producing 650PS (641bhp) and 678Nm (500lb ft) of torque, it is a no compromise open-top high performance supercar with optimised levels of performance, handling and driver enjoyment. The secret of its success is its carbon fibre MonoCell chassis, which needs no extra strengthening to provide the necessary rigidity or safety when developing a convertible. This keeps any weight increase to a minimum, meaning the McLaren 650S Spider offers all the enjoyment and driver appeal of the fixed-roof sibling – but with the added appeal of roof-down driving. The 650S Spider is fitted with an electrically retractable hard top, which can be automatically raised or lowered on the move in less than 17 seconds. Building on the success of the MP4 12C, with which it shares much, the 650S series, first seen at the 2014 Geneva Show has proved very popular, helping to establish the brand as a serious rival to the established supercar players. Production ended when the even faster (and costlier) 720S arrived in 2017.

Now an established part of the McLaren range, the 570S along with its slightly cheaper and less powerful brother, the 540C, was revealed at the 2015 New York Auto Show, going on sale towards the end of that year. These were labelled as part of McLaren’s Sports Series. This mid-engine sportscar features the lightweight carbon fibre MonoCell II chassis, and a highly efficient 3.8-litre twin turbo V8 engine generating 562bhp and 443lb/ft of torque. Although the model has been conceived with a greater focus on day-to-day usability and refinement, it is still very much a pure McLaren, boasting a class-leading power-to-weight ratio of 434PS per tonne, and electrifying performance. The 570S Coupé accelerates from 0 to 100km/h in just 3.2 seconds, reaches 200km/h (124mph) in 9.5 seconds, and on to a top speed of 204mph. Pricing for the 570S Coupé started at £143,250, though like all cars of this type, that figure can quickly rise once you raid the options list.

The McLaren GT is the company’s first dedicated grand tourer and is based on the same platform underpinning the 720S with the addition of a carbon fibre rear deck topped by a glazed tailgate creating significantly greater storage capacity. The GT was first announced at the 2019 Geneva Motor Show, but full details of the car were not released until May 15 of the same year. The GT features a new variation of the 3,994 cc twin-turbocharged M840T V8 engine found in the 720S. Having a new dedicated codename of M840TE, the new engine has smaller turbochargers that deliver lower peak performance than its Super Series variant but greater low RPM-performance and responsiveness. The GT has a rated power output of 620 PS at 7,000 rpm, and the maximum torque is 465 lb/ft (630 Nm) at 5,500 rpm. The suspension system in the GT is also derived from the system in the 720S. The car utilizes double wishbones at the front and rear axles, and a modified version of the ProActive Chassis Control II active damping system called Proactive Damping Control. The company claims that the GT has a top speed of 326.7 km/h (203 mph), it can accelerate from 0–60 mph in 3.1 seconds, and 0–200 km/h (0–124 mph) in 9 seconds. The McLaren GT features 150 litres of storage space at the front and 420 litres in the rear, accommodating a full-sized set of golf clubs. Napa leather is standard upholstery, but drivers can also choose from a softer hide made by Bridge of Weir Leather in Scotland or in the future, cashmere. The new comfort seats have increased shoulder padding and back support, with electrical adjustment and heating as standard on Pioneer and Luxe models. A 7-inch touchscreen mounted in the centre controls a revamped infotainment system and is supplemented by a 12.3-inch driver information display which changes in layout depending on whether Comfort, Sport or Track mode is selected.

Also here was the 750S, the replacement for the 720S that apparently has far more changes than are obvious from a quick glance and the technical very advanced Artura.

MERCEDES-BENZ

Oldest of the Mercedes models here was this 190SL. Produced between May 1955 and February 1963, having first been seen in prototype at the 1954 New York Auto Show, this was designed as a more affordable sports car than the exclusive and rather pricey 300SL, sharing its basic styling, engineering, detailing, and fully independent suspension. While both cars had double wishbones in front and swing axles at the rear, the 190 SL did not use the 300 SL’s purpose-built W198 tubular spaceframe. Instead, it was built on a shortened monocoque R121 platform modified from the W120 saloon. The 190 SL was powered by a new, slightly oversquare 105 PS Type M121 1.9 litre four cylinder engine. Based on the 300 SL’s straight six, it had an unchanged 85 mm bore and 4.3 mm reduced 83.6 mm stroke, was fitted with twin-choke dual Solex carburettors, and produced 120 gross hp. In detuned form, it was later used in the W120 180 and W121 190 models. Both the 190 SL and the 300 SL were replaced by the Mercedes-Benz 230SL in 1963.

The Mercedes-Benz “Ponton” series is a range of sedans / saloon car models from Mercedes-Benz, introduced starting in 1953, and subsequently nicknamed ‘Ponton’ (the German word for “pontoon”), referring to its ponton styling, a prominent styling trend that unified the previously articulated hood, body, fenders and runnings boards into a singular, often slab-sided envelope. At the time, Mercedes itself did not refer to any of its cars using the nickname. Mercedes stretched the ‘Ponton’ saloons into a range that became the automaker’s dominant production models until 1959. Mercedes-Benz emerged from World War II as a carmaker best known in the early 1950s for its expensive Mercedes-Benz 300 Adenauers and exclusive 300 S sports tourers. Both were largely handbuilt body on frame vehicles. Its low end was anchored by the dated pre-war designed 170. Seeking to expand its production, Mercedes turned toward the unibody concept to design a line of mass-produced cars. Work began in earnest on the pontons bodied cars in 1951, with a design focused on passenger comfort and safety. Head of the design team was Dr. Fritz Nallinger. Styling was headed by Karl Wilfert. Also in the design team was Béla Barényi, who conceived the passive safety (crash protection) engineering of the body. The 1953 W120 180 four-cylinder sedans were Mercedes’ second totally new series of passenger cars since World War II, following the 1951 introduction of the top of the range W186 300 “Adenauer”, and replaced the pre-war-designed W136 170 and 170 S. Contrasting very visibly with the traditional distinct fenders on that body-on-frame model and the ones before it, the ‘Pontons’ were Mercedes’ first monocoque, unitary body production models. Mercedes expanded the base Ponton model into a diversified line, developing multiple series based on the 180, by introducing more engines and stretching the body. Six-cylinder models received a longer nose, and ‘S’-models also had a longer passenger compartment, offering more legroom. A six-cylinder coupe and convertible were further derived, and a shortened floorpan of the four-cylinder sedan was also modified to serve as the structure for the W121 190 SL roadster. The ‘Ponton’ saloons were the automaker’s main production models until 1959, adding up to 80% of Mercedes-Benz car production between 1953 and 1959, with some models lasting until 1962. The first of the ‘Ponton’ models to go into production was the 1953 W120 180, 1.8 L four-cylinder, four-door sedan, available as the 180 petrol and the 180D diesel. In 1954 the W180 six-cylinder executive / luxury model 220a was added, developed mostly by stretching the W120’s body by 170 mm (6.7 in), complemented by a new rear suspension, and giving it the longer straight six M180 engine. The added length was divided between 100 mm (3.9 in) added forward of the firewall to accommodate the two cylinder larger engine, and 70 mm (2.8 in) to the rear seating area for additional legroom; the boots stayed the same. In 1956, the six-cylinder model was expanded into an entire range. The 220a gained a second carburettor and was upgraded to become the 220S, shortly joined in the line by new distinctively bodied, shorter wheelbase two-door coupe and convertible models. A third saloon series, the W105 219 was created by grafting the six-cylinder nose onto the shorter body of the four-cylinder from the firewall aft. In 1956, the four-cylinder model also received an all new, short-stroke 1.9 L petrol engine option, the W121 model 190, joined in 1958 by a 1.9 litre diesel. In 1958, the 220S models were upgraded with fuel injection, and became the W128 220 SE series. The models 180 D and 190 D received further updates in 1959 and 1961. The range was succeeded by the range of “Heckflosse” (or “Fintail”) models.

Chronologically, next up was a W111 “FinTail”, the staple of the Benz range through the early 1960s. Mercedes-Benz had emerged from World War II in the early 1950s with the expensive 300 Adenauers and the exclusive 300SL grand tourers that gained it fame, but it was the simple unibody Pontons which comprised the bulk of the company’s revenues. Work on replacing these cars began in 1956 with a design focused on passenger comfort and safety. The basic Ponton cabin was widened and squared off, with a large glass greenhouse improving driver visibility. A milestone in car design were front and rear crumple zones for absorbing kinetic energy on impact. The automaker also patented retractable seatbelts. Series production of the first of the new cars, the W111 4-door sedan began in August 1959, with the car making its debut at the Frankfurt Auto Show in autumn. Initially the series consisted of the 220b, 220Sb, and 220SEb. These replaced the 219 W105, the 220S W180 and the 220SE W128 Ponton sedans respectively. The 220b was an entry-level version with little chrome trim, simple hubcaps, and basic interior trim that lacked pockets on doors. Prices were DM16,750, 18,500 and 20,500, with a rough sales ratio of 1:2:1. All modes shared the 2195 cc straight-six engine carried over from the previous generation, producing 95 hp and capable of accelerating the heavy car to 160 km/h. The 220Sb featured twin carburettors and produced 110 hp raising top speed to 103 mph and improving 0–100 km/h acceleration to 15 seconds. The top range 220SEb featured Bosch fuel injection producing 120 hp at 4800 rpm, with top speed of 107 mph and a 0–100 km/h in 14 seconds. In 1961, the W111 chassis and body were shared with the even more basic 4-cylinder W110 and a luxury version built on the W111 chassis with its body and the 3-litre M189 big block 6-cylinder engine, many standard power features, and a high level of interior and exterior trim, was designated the W112. A 2-door coupe/cabriolet version of the W111/W112 was also produced. In summer 1965, the new Mercedes-Benz W108 sedan was launched and production of the first generation of W111’s was ended. Totals were: 220b – 69,691, 220Sb – 161,119, and 220SEb – 65,886. Earlier that year, Mercedes-Benz gave its budget-range W110 series a major facelift, opting to continue producing the W111 as a new model 230S. The previously 4-cylinder W110 received a 6-cylinder, practically identical in terms of chassis and drivetrain. In 1965 the W110 was equipped with a six-cylinder engine, creating the model 230. The 230S, became a flagship model of the Mercedes passenger cars (predecessors to today’s S-class). The 230S was visually identical to the 220S, with a modernised 2306 cc M180 engine with twin Zenith carburettors producing 120 hp.In this final configuration a total of 41,107 cars were built up to January 1968, when the last of 4-door fintails left the production line. Between 1959 and 1968 a total of 337,803 W111s were built.

This one comes from the W108 family. The car’s predecessor, the Mercedes-Benz W111 (produced 1959–1971) helped Daimler develop greater sales and achieve economy of scale production. Whereas in the 1950s, Mercedes-Benz was producing the coachwork 300 S and 300 SLs and all but hand-built 300 Adenauers alongside conveyor assembled Pontons (190, 190SL and 220) etc., the fintail (German: Heckflosse) family united the entire Mercedes-Benz range of vehicles onto one automobile platform, reducing production time and costs. However, the design fashion of the early 1960s changed. For example, the tail fins, originally intended to improve aerodynamic stability, died out within a few years as a fashion accessory. By the time the 2-door coupé and cabriolet W111s were launched, the fins lost their chrome trim and sharp appearance, the arrival of the W113 Pagoda in 1963 saw them further buried into the boot’s contour, and finally disappeared on the W100 600 in 1964. The upgrade of the W111 began under the leadership of designer Paul Bracq in 1961 and ended in 1963. Although the fins’ departure was the most visible change, the W108 compared to the W111 had a lower body waist line that increased the window area, (the windscreen was 17 percent larger than W111). The cars had a lower ride (a decrease by 60 mm) and wider doors (+15 mm). The result was a visibly new car with a more sleek appearance and an open and spacious interior. The suspension system featured a reinforced rear axle with hydropneumatic compensating spring. The car sat on larger wheels (14”) and had disc brakes on front and rear. The W109 was identical to the W108, but featured an extended wheelbase of 115 mm (4.5 in) and self-levelling air suspension. This was seen as a successor to the W112 300SEL that was originally intended as an interim car between the 300 “Adenauer” (W189) and the 600 (W100) limousines. However, its success as “premium flagship” convinced Daimler to add an LWB car to the model range. From that moment on, all future S-Class models would feature a LWB line. Although the W108 succeeded the W111 as a premium range full-size car, it did not replace it. Production of the W111 continued, however the 230S was now downgraded to the mid-range series, the Mercedes-Benz W110, and marketed as a flagship of that family until their production ceased in 1968. The W108 is popular with collectors and the most desirable models to collect are the early floor shift models with the classic round gear knob and the 300 SEL’s. The car was premièred at the Frankfurt Auto Show in 1965. The initial model lineup consisted of three W108s: 250S, 250SE, and 300SE, as well as a sole W109, the 300SEL. Engines for the new car were carried over from the previous generation, but enlarged and refined. The 250S was the entry-level vehicle fitted with a 2496 cm³ Straight-six M108 engine, with two dual downdraft carburettors, delivering 130 bhp at 5400 rpm which accelerated the car to 100 km/h (62 mph) in 13 seconds (14 on automatic transmission) and gave a top speed of 182 km/h (177 on auto). The 250SE featured an identical straight-six, but with a six-plunger fuel injection (designated M129) with performance improved to 150 bhp at 5500 rpm, which decreased 0-100 acceleration by one second and increased top speed by 11 km/h (7 mph) for both manual and automatic versions. Both the 300SE and 300SEL came with the M189 2996 cm³ engine, originally developed for the Adenauers. It had a modern six-plunger pump that adjusted automatically to accelerator pedal pressure, engine speed, atmospheric pressure, and cooling water temperature, to deliver the proper mixture depending on driving conditions. Producing 170 bhp at 5,400 rpm the cars could accelerate to 200 km/h (195 km/h with automatic transmission) and reach 100 km/h (62 mph) in 12 seconds. The cylinder capacity of the three litre Mercedes engine was unchanged since 1951. From 1965 to 1967, fewer than 3,000 W109s were produced. However, approximately 130,000 of the less powerful 250 S/SE models were built during the first two years of the W108/109’s existence. By 1967 the fuel consumption of the 3 litre unit in this application was becoming increasingly uncompetitive.

By 1955, Mercedes-Benz Technical Director Prof. Fritz Nallinger and his team held no illusions regarding the 190 SL’s lack of performance, while the high price tag of the legendary 300 SL supercar kept it elusive for all but the most affluent buyers. Thus Mercedes-Benz started evolving the 190 SL on a new platform, model code W127, with a fuel-injected 2.2 litre M127 inline-six engine, internally denoted as 220SL. Encouraged by positive test results, Nallinger proposed that the 220SL be placed in the Mercedes-Benz program, with production commencing in July 1957. However, while technical difficulties kept postponing the production start of the W127, the emerging new S-Class W112 platform introduced novel body manufacturing technology altogether. So in 1960, Nallinger eventually proposed to develop a completely new 220SL design, based on the “fintail” W 111 sedan platform with its chassis shortened by 11.8 in, and technology from the W112. This led to the W113 platform, with an improved fuel-injected 2.3 litre M127 inline-six engine and the distinctive “pagoda” hardtop roof, designated as 230 SL. The 230 SL made its debut at the prestigious Geneva Motor Show in March 1963, where Nallinger introduced it as follows: “It was our aim to create a very safe and fast sports car with high performance, which despite its sports characteristics, provides a very high degree of travelling comfort”. The W113 was the first sports car with a “safety body,” based on Bela Barényi’s extensive work on vehicle safety: It had a rigid passenger cell and designated crumple zones with impact-absorbing front and rear sections built into the vehicle structure. The interior was “rounded,” with all hard corners and edges removed, as in the W111 sedan. Production of the 230 SL commenced in June 1963 and ended on 5 January 1967. Its chassis was based on the W111 sedan platform, with a reduced wheelbase by 11.8 in, recirculating ball steering (with optional power steering), double wishbone front suspension and an independent single-joint, low-pivot swing rear-axle with transverse compensator spring. The dual-circuit brake system had front disc brakes and power-assisted rear drum brakes. The 230 SL was offered with a 4-speed manual transmission, or an optional, very responsive fluid coupled (no torque converter) 4-speed automatic transmission, which was popular for US models. From May 1966, the ZF S5-20 5-speed manual transmission was available as an additional option, which was particularly popular in Italy. The 2,308 cc M127.II inline-six engine with 150 hp and 145 lb/ft torque was based on Mercedes-Benz’ venerable M180 inline-six with four main bearings and mechanical Bosch multi-port fuel injection. Mercedes-Benz made a number of modifications to boost its power, including increasing displacement from 2,197 cc, and using a completely new cylinder head with a higher compression ratio (9.3 vs. 8.7), enlarged valves and a modified camshaft. A fuel injection pump with six plungers instead of two was fitted, which allowed placing the nozzles in the cylinder head and “shooting” the fuel through the intake manifold and open valves directly into the combustion chambers. An optional oil-water heat exchanger was also available. Of the 19,831 230 SLs produced, less than a quarter were sold in the US. Looking identical, the 250 SL was introduced at the 1967 Geneva Motor Show. Production had already commenced in December 1966 and ended in January 1968. The short one-year production run makes the 250 SL the rarest of the W113 series cars. The 250 SL retained the stiffer suspension and sportier feel of the early SLs, but provided improved agility with a new engine and rear disc brakes. Range also improved with increased fuel tank capacity from 65 litres to 82. Like its predecessor, the 250 SL was offered with a 4-speed automatic transmission, and 4-speed or ZF 5-speed manual transmissions. For the first time, an optional limited slip differential was also available. The main change was the use of the 2,496 cc M129.II engine with a larger stroke, increased valve ports, and seven main bearings instead of four. The nominal maximum power remained unchanged at 150 hp, but torque improved from 145 lb/ft to 159 lb/ft. Resiliency also improved with a new cooling water tank (“round top”) with increased capacity and a standard oil-water heat exchanger. The 250 SL also marked the introduction of a 2+2 body style, the so-called “California Coupé”, which had only the removable hardtop and no soft-top: a small fold-down rear bench seat replaced the soft-top well between passenger compartment and boot. It is estimated that only 10% of the 250SLs that were brought into America were California Coupes. Of the 5,196 250 SLs produced, more than a third were sold in the US.The 280 SL was introduced in December 1967 and continued in production through 23 February 1971, when the W113 was replaced by its successor, the entirely new and substantially heavier R107 350 SL. The main change was an upgrade to the 2,778 cc M130 engine with 170 hp and 180 lb/ft, which finally gave the W113 adequate power. The performance improvement was achieved by increasing bore by 4.5 mm (0.2 in), which stretched the limits of the M180 block, and required pairwise cylinder casts without cooling water passages. This mandated an oil-cooler, which was fitted vertically next to the radiator. Each engine was now bench-tested for two hours prior to being fitted, so their power specification was guaranteed at last. The M130 marked the final evolution of Mercedes-Benz’ venerable SOHC M180 inline-six, before it was superseded by the entirely new DOHC M110 inline-six introduced with R107 1974 European 280 SL models. For some time, it was also used in the W 109 300 S-Class, where it retired the expensive 3 liter M189 alloy inline-six. Over the years, the W 113 evolved from a sports car into a comfortable grand tourer, and US models were by then usually equipped with the 4-speed automatic transmission and air conditioning. Manual transmission models came with the standard 4-speed or the optional ZF 5-speed, which was ordered only 882 times and thus is a highly sought-after original option today. In Europe, manual transmissions without air conditioning were still the predominant choice. Of the 23,885 280 SLs produced, more than half were sold in the US.

With prices of the classic Pagoda model having risen to unaffordable for most people attention has started to switch to it successor, the R107 SL range, which had a long production life, being the second longest single series ever produced by the automaker, after the G-Class. The R107 and C107 took the chassis components of the mid-size Mercedes-Benz W114 model and mated them initially to the M116 and M117 V8 engines used in the W108, W109 and W111 series. The SL variant was a 2-seat convertible/roadster with standard soft top and optional hardtop and optional folding seats for the rear bench. The SLC (C107) derivative was a 2-door hardtop coupe with normal rear seats. The SLC is commonly referred to as an ‘SL coupe’, and this was the first time that Mercedes-Benz had based a coupe on an SL roadster platform rather than on a saloon, replacing the former saloon-based 280/300 SE coupé in Mercedes lineup. The SLC was replaced earlier than the SL, with the model run ending in 1981, with a much larger model, the 380 SEC and 500SEC based on the new S class. Volume production of the first R107 car, the 350 SL, started in April 1971 alongside the last of the W113 cars; the 350 SLC followed in October. The early 1971 350SL are very rare and were available with an optional 4 speed fluid coupling automatic gearbox. In addition, the rare 1971 cars were fitted with Bosch electronic fuel injection. Sales in North America began in 1972, and cars wore the name 350 SL, but had a larger 4.5L V8 with 3 speed auto (and were renamed 450 SL for model year 1973); the big V8 became available on other markets with the official introduction of the 450 SL/SLC on non-North American markets in March 1973. US cars sold from 1972 through 1975 used the Bosch D Jetronic fuel injection system, an early electronic engine management system. From July 1974 both SL and SLC could also be ordered with a fuel-injected 2.8L straight-6 as 280 SL and SLC. US models sold from 1976 through 1979 used the Bosch K Jetronic system, an entirely mechanical fuel injection system. All US models used the 4.5 litre engine, and were called 450 SL/SLC. In September 1977 the 450 SLC 5.0 joined the line. This was a homologation version of the big coupé, featuring a new all-aluminium five-litre V8, aluminium alloy bonnet and boot-lid, and a black rubber rear spoiler, along with a small front-lip spoiler. The 450SLC 5.0 was produced in order to homologate the SLC for the 1978 World Rally Championship. Starting in 1980, the 350, 450 and 450 SLC 5.0 models (like the 350 and 450 SL) were discontinued in 1980 with the introduction of the 380 and 500 SLC in March 1980. At the same time, the cars received a very mild makeover; the 3-speed automatic was replaced by a four-speed unit, returning to where the R107 started in 1971 with the optional 4 speed automatic 350SL. The 280, 380 and 500 SLC were discontinued in 1981 with the introduction of the W126 series 380 and 500 SEC coupes. A total of 62,888 SLCs had been manufactured over a ten-year period of which just 1,636 were the 450 SLC-5.0 and 1,133 were the 500 SLC. Both these models are sought by collectors today. With the exception of the SL65 AMG Black Series, the SLC remains the only fixed roof Mercedes-Benz coupe based on a roadster rather than a sedan. Following the discontinuation of the SLC in September 1981, the 107 series continued initially as the 280, 380 and 500 SL. At this time, the V8 engines were re-tuned for greater efficiency, lost a few hp and consumed less fuel- this largely due to substantially higher (numerically lower) axle ratios that went from 3.27:1 to 2.47:1 for the 380 SL and from 2.72:1 to 2.27:1 for the 500 SL. From September 1985 the 280 SL was replaced by a new 300 SL, and the 380 SL by a 420 SL; the 500 SL continued and a 560 SL was introduced for certain extra-European markets, notably the USA, Australia and Japan. Also in 1985, the Bosch KE Jetronic was fitted. The KE Jetronic system varied from the earlier, all mechanical system by the introduction of a more modern engine management “computer”, which controlled idle speed, fuel rate, and air/fuel mixture. The final car of the 18 years running 107 series was a 500 SL painted Signal red, built on August 4, 1989; it currently resides in the Mercedes-Benz museum in Stuttgart.

Mercedes-Benz introduced the W123 four-door versions on 29 January 1976. While there were some technical similarities to their predecessors, the new models were larger in wheelbase and exterior dimensions. The styling was also updated, although stylistic links with the W114 / W115 were maintained. Initially, all models except 280/280E featured quad unequal-size round headlights and the latter large rectangular units. When facelifted, these units became standard across the range. All W115 engines were carried over, with the 3-litre 5-cylinder diesel model being renamed from “240D 3.0” to “300D” (as it had already been called before in North American markets). The only new engine was the 250’s 2,525 cc inline-six (Type M123, a short-stroke version of the 2.8-litre six Type M110) that replaced the old 2,496 cc Type M114 “six”. In the spring of 1976, a Coupé version was introduced on a shorter wheelbase than the saloon (106.7 in versus 110.0 in). This W123C/CE was available as a 230C (later 230CE) and as a 280C/CE in most markets; in North America there were additional 300CD versions with naturally aspirated, later turbocharged 3-litre diesel engines. In North America, buyers favored diesel engines for upmarket cars, while CAFE legislation meant that Mercedes-Benz North America had to lower their corporate average fuel economy. This led to the introduction of a few diesel models only sold in the United States. It is a tribute to the car’s instant popularity – and possibly to the caution built into the production schedules – that nine months after its introduction, a black market had developed in Germany for Mercedes-Benz W123s available for immediate delivery. Customers willing to order new cars from their local authorised dealer for the recommended list price faced waiting times in excess of twelve months. Meanwhile, models that were barely used and were available almost immediately commanded a premium over the new price of around DM 5,000. From August 1976, long-wheelbase versions (134.8 in) were produced. These were available as 7/8 seater saloons with works bodies or as a chassis with complete front body clip, the latter serving as the base for ambulance and hearse bodies by external suppliers like Binz or Miesen. These “Lang” versions could be ordered as 240D, 300D and 250 models. At the Frankfurt Auto Show in September, 1977 the W123T estate was introduced; the T in the model designation stood for “Touring and Transport”. All engines derivative except “200TD” were available in the range. T production began in March, 1978 in Mercedes’ Bremen factory. It was the first factory-built Mercedes-Benz estate, previous estates had been custom-built by external coachbuilders, such as Binz. In early 1979, the diesel models’ power output was increased; power rose from 54 hp to 59 hp in the 200D, from 64 hp to 71 hp in the 240D and from 79 hp to 87 hp in the 300D; at the same time, the 220D went out of production. The first Mercedes turbo diesel production W123 appeared in September, 1981. This was the 300 TD Turbodiesel, available with automatic transmission only. In most markets, the turbocharged 5-cylinder 3-litre diesel engine (Type OM617.95) was offered only in the T body style, while in North America it was also available in saloon and coupé guises. June 1980 saw the introduction of new four-cylinder petrol engines (Type M102). A new 2-litre four with shorter stroke replaced the old M115, a fuel-injected 2.3-litre version of this engine (in 230E/TE/CE) the old carburettor 230. Both engines were more powerful than their predecessors. In 1980/81, the carburettor 280 versions went out of production; the fuel-injected 280E continued to be offered. In September 1982, all models received a mild facelift. The rectangular headlights, previously fitted only to the 280/280E, were standardised across the board, as was power steering. Since February 1982, an optional five-speed manual transmission was available in all models (except the automatic-only 300 turbodiesel). W123 production ended in January, 1986 with 63 final T-models rolling out. Most popular single models were the 240D (455,000 built), the 230E (442,000 built), and the 200D (378,000 built). The W123 introduced innovations including ABS (optional from August, 1980), a retractable steering column and an airbag for the driver (optional from 1982). Power (vacuum servo) assisted disc brakes were standard on all W123s. Available options included MB-Tex (Mercedes-Benz Texturized Punctured Vinyl) upholstery or velour or leather upholstery, interior wood trim, passenger side exterior mirror (standard on T models), 5-speed manual transmission (European market only), 4-speed automatic transmission (standard in turbodiesel models), power windows with rear-seat switch cut-outs, vacuum powered central locking, rear-facing extra seats (estate only), Standheizung (prestart timer-controlled engine heating), self-locking differential, sun roof, air conditioning, climate control, “Alpine” horn (selectable quieter horn), headlamp wipers (European market only), Tempomat (cruise control), power steering (standard after 1982/08), seat heating, catalytic converter (available from 1984 for California only, from fall (autumn) 1984 also in Germany for the 230E of which one thousand were built). These days, the cars are very popular “youngtimer” classics, with all models highly rated.

Designed in 1984, and launched in 1989, the R129 was based on the shortened floorpan of the Mercedes-Benz W124 and featured many innovative details for the time, for instance electronically controlled damping (Adaptive Damping System ADS, optional) and a hidden, automatically extending roll-over bar. The R107’s somewhat dated rear suspension with semi-trailing arms gave way to a modern multi-link axle. The number of standard features was high, with electric action for the windows, mirrors, seats and hydraulic convertible top. This car has the distinction of being the first passenger vehicle to have seat belts integrated into the seats as opposed to anchoring to the floor, B-pillar, and transmission tunnel. Initially, there were three different engines available: 300 SL with a M103 3.0 L 12-valve SOHC I6 (188 bhp), a 300 SL-24 with a M104 3.0 L 24-valve DOHC I6 (228 bhp)  and the 500 SL with a M119 5.0 L 32-valve DOHC V8 (322 bhp) . These were joined in July 1992 by the 600 SL with a M120 6.0 L 48-valve DOHC V12 (389 bhp). There was a choice of 5-speed manual or 4–5 speed automatic for the six-cylinder cars; the V8 and V12 could only be ordered with a 4-speed automatic gearbox. In autumn 1993 Mercedes-Benz rearranged names and models. Also, the 300 SL and 300 SL-24 were respectively replaced by:  SL 280 with a M104 2.8 L 24-valve DOHC I6 (190 bhp) and the SL 320 with a M104 3.2 L 24-valve DOHC I6 (228 bhp). Only the 280 was available with a manual gearbox. SL 500 and 600 continued with their respective engines. Starting in 1993, the cars were re-designated. For example, 500 SL became SL 500. Starting in model year 1994, Mercedes-Benz offered special SL models from time to time, such as the Mille Miglia edition cars of model year 1994 or the SL edition of model year 2000. 1994 cars had minor updates for the car and then in 1995 there was a minor facelift for the car, with the front fender vents updated to only 2 rounded slots, rather than 3 squared slots, and bumpers in body colour. The V8 and V12s were upgraded to 5 speed electronic transmission, the previous transmission was hydraulic 4-speed. A second facelift occurred in 1998 with many detailed changes applied, including  new external mirrors, 17″ wheels and new bumpers. Also new were the engines, a SL 280 with a M112 2.8 L 18-valve SOHC V6 (201 bhp);  SL 320 with a M112 3.2 L 18-valve SOHC V6 (221 bhp) and a  SL 500 with a M113 5.0 L 24-valve SOHC V8 (302 bhp). The V12 engine remained unchanged. The car was replaced by the R230 generation SL in 2001, after 213,089 had been built. There were a number of very low volume AMG versions of the car, including this SL70 AMG. This was powered by a 7.1 litres (7,055 cc) V12 engine developing 496 PS (489 bhp) at 5,500 rpm and a maximum torque of 720 Nm (531 lb/ft) at 3,900 rpm. It was a bored out version of M120 6.0 V12 and with a longer stroke. Produced between 1996 and 1997, just 150 units were made.

Rather more recent was this example of the elegant CLK Cabriolet.

There were a number of examples of the AMG GT here, too.

MG

Unless you go back to the 1930s. when MG made a few high performance cars which had racing more in mind than road use, the only model to get anywhere supercar status that bears the famous roundel is the SV, and this was also represented here. This car came about after MG-Rover acquired Qvale of Italy. Taking the Qvale Mangusta as a base, a car which had been designed, but not quite made production, MG Rover allocated the project code X80 and set up a subsidiary company, MG X80 Ltd., to produce their new model. A big factor behind the project was that was seen as having the potential sales in the United States, as the Mangusta had already been homologated for the American market. The MG X80 was originally revealed as a concept car in 2001. However, the styling was considered too sedate, so when the production model, now renamed MG XPower SV, was eventually launched the following year, designer Peter Stevens had made the car’s styling more aggressive. The conversion from a clay model to a production car, including all requirements, was done in just 300 days by the Swedish company Caran. The production process was complex, partly caused by the use of carbon fibre to make the body panels. The basic body parts were made in the UK by SP Systems and then shipped to Belco Avia near Turin for assembly into body panels. These were then assembled into a complete body shell and fitted onto the box frame chassis and running gear and shipped to MG Rover’s Longbridge factory to be trimmed and finished. Several of the cars’ exterior and interior parts were borrowed from current and past Fiat models. The headlights, for example, were taken from a Punto Mk.2 and the rear lights borrowed from a Fiat Coupe. The goal had been to get a street price of under £100,000, and on launch, the base model came in well under that at £65,000, and even the uprated XPower SV-R model was priced at £83,000. Those were ambitious prices for a car bearing MG badges, though, so not surprisingly, sales were slow. It is understood that just 82 cars were produced excluding the 4 ‘XP’ pre-production prototypes. This included a few pre-production and show cars which were later dismantled, before production was stopped due to lack of sales. Most were sold to private owners, with the final ones being sold to customers in early 2008.

MORGAN

Initially seen at the 2005 Geneva motor show as a bespoke car built for a well respected Morgan customer Prince Eric Sturdza of Banque Baring Sturdza in Geneva, the AeroMax was the next development of the Aero chassis. It is said that the car is named after Charles Morgan’s son Max. Due to the level of interest at the show and with the agreement of Prince Sturdza a limited production run of 100 in celebration of Morgan’s centenary was agreed, with final numbers ending slightly over this due to replacement of crashed cars. Production was initiated in 2008 and completed in 2009. The iconic design was created by Matt Humphries a 21 year old Coventry University Graduate working at the factory. The Empire Line or Art Deco influenced styling has often been compared to cars such as classic Bugatti’s whilst retaining a clear family relationship with Morgan’s other cars. Many refinements were made to the overall shape including the use of the rear lights from the Lancia Thesis, flush fit of the doors and changes to the interior finish. The Rays alloy wheels introduced on this model became popular on other models following the AeroMax. It was the first Morgan to have a retail price above £100,000 at £110,000 but sold out within a few months. Owners have included Richard Hammond, Rowan Atkinson and Paul O’Grady.Taillights used on AeroMax, Aero Supersports, Aero Coupe and Aero 8 Series 5 were borrowed from Lancia Thesis.

Oldest Morgan here was this Plus 4 Drophead Coupe. After World War II Morgan re-introduced their 4/4 model fitted with a 1267 cc Standard engine. This continued in production until it was replaced by the larger Plus 4 announced at the 1950 Earl’s Court Motor Show. The Plus 4 at its introduction was fitted with a 2088 cc Standard Vanguard engine installed on a widened and strengthened 4/4 chassis with a wheelbase lengthened by 4 in (102 mm). Hydraulic brakes, initially all drum, were fitted for the first time on a Morgan. In 1953 a higher performance version was announced with the 1991 cc, 90 bhp straight-four engine as used in the Triumph TR2 (a development of the Vanguard motor). The 68 bhp Vanguard engine continued to be available until late in 1956. Beginning in very late 1953, the radiator grille was now surrounded by a cowl that blended into the bonnet; initial cars received an interim version which only curved backwards at the top (nineteen examples were built of this design), followed by a transition version using the final cowled design which also curves backwards at the sides coupled with lower-mounted headlamps. The final design, with higher mounted headlight pods and the badge above the grille appeared sometime in 1954; flat radiator cars were frequently returned to the factory to have the front updated, along with various technical upgrades. Front disc brakes became an option in 1959 and were standardised in 1960. From 1956 the 1991 cc 100 bhp, Triumph TR3 engine was used and from 1962 the engine was the Triumph TR4 unit, which increased displacement to 2138 cc. The bonnet of the Triumph-engined Plus 4 fitted so closely to the engine that there was no room for an air filter. In 1955 the less powerful 4/4 model re-appeared in phase II form. The 96 in (2,438 mm) wheelbase of the Plus 4 was adopted by the 4/4 when it reappeared, after which the two models were for most purposes the same length and width. Body styles available were a 2-seat sports, 4-seat sports, and more luxurious drophead coupé (DHC). A 4-seater version of the drophead coupé was available in 1954–1956 only; due to the complexity of the build, Morgan lost money on every one of these cars (which can be recognized by having a regular boot with a lid) and the type was discontinued after 51 examples had left the factory gates. In total, 556 examples of the various drophead coupés were built between 1950 and January 1969; 117 of them were early, flatnose designs.

NOBLE

The Noble M600 is a handbuilt British sports car manufactured by low volume automobile manufacturer Noble Automotive in Leicestershire. Construction of the car is of stainless steel and carbon fibre. The car uses a twin-turbocharged Volvo/Yamaha V8 engine. The M600 comes in three specifications, the standard; which uses a fibre glass body; the carbon sport which uses a carbon-fibre body and the Speedster which is basically a targa top version. The M600 is hand-built by a team of 20 workers at the company’s Leicestershire facility. The M600 uses a steel backbone and aluminium chassis which is the same chassis used on the stillborn M15. The standard model uses carbon-fibre for vital body parts of the car and this allows it to have a curb weight of 1,250 kg (2,756 lb), although when independently tested, the standard model weighed 1,305 kg (2,877 lb). The M600 uses a 4,414 cc Yamaha-built Volvo B8444S 60º V8 engine which is also used in the Volvo XC90 and S80. The engine used in the M600 is manufactured by Motorkraft in the US from B8444S crate engines with Garrett AiResearch twin-turbochargers equipped with variable boost. This allows the buyer to choose from variable power outputs ranging from 450 hp (Road setting, 0.6 bar (8.7 psi) pressure), 550 hp (Track setting, 0.8 bar (12 psi)) and 650 hp (Race setting, 1 bar (15 psi)) through the use of a switch present on the dashboard. The engine also features a MoTeC M190 and Injector Dynamics ID725 electronic fuel injection. It has a compression ratio of 9.50:1. It uses an Oerlikon Graziano transaxle six-speed manual gearbox and has the redline set at 7,000 rpm. At least, a pre-production variant of the Speedster is also equipped with an automatic gearbox. The M600 uses steel brake discs with six piston calipers at the front and four piston calipers at the rear. The brakes are designed by Britain-based braking specialist Alcon. Owing to the driver focused nature of the car, there is no Anti-lock Braking System installed and the brakes have limited servo assistance. The interior of the car has twin hide upholstery and gloss carbon-fibre trim as standard. Buyers have the choice to choose from leather, suede an advantage upholstery along with knurled wood trim and wool carpeting. The switches and instrumentation are bespoke to the M600, although some components are shared with Jaguar and Aston Martin models. The car is equipped with an adjustable steering column and driver’s seat while the pedals are offset to the left. The pedals are adjusted according to the owner’s preference in order to provide a good driving position. A highlight of the interior is the engine power control knob, similar to Ferrari’s Manettino dial, which allows the driver to choose from variable engine power outputs along with related turbo boost pressure (Road, Track and Race). The knob is present ahead of the gearshift knob on the dashboard. A traction control switch activates the limited traction control which is present to avoid oversteer. The interior is based on simplicity and is driver focused, inspired by the Ferrari F40 and due to this, it does away with climate control and modern infotainment systems. The car was driven two times on the British motoring show Top Gear. First in Series 14, Episode 5 by Jeremy Clarkson, who praised the car considerably and the show’s racing driver the Stig took it around the Top Gear track and it did a 1:17.7 on a cold day, beating the Pagani Zonda F Roadster and the Bugatti Veyron. In Series 18, Episode 1 co-host Richard Hammond drove a left-hand drive version of the car through Italy and the clutch failed, causing clutch material to damage the gearbox; Noble sent the production team another car. Later in the same episode Hammond drove it during a challenge where he attempted to beat a laptime set by the Stig at the Autodromo Enzo e Dino Ferrari on the outskirts of Imola. Despite the breakdown, Hammond heaped considerable praise on the car. It has also been featured in the American adaptation of the show where it receives considerable praise, the main “challenge” was to reach its top speed, the vehicle reached 215 mph (346 km/h), but stopped because the vehicle ran out of space on the runway it was being tested on.

PAGANI

The Pagani Huayra is a mid-engine sports car produced by Italian sports car manufacturer Pagani, superseding the company’s previous offering, the Zonda. It is named after Wayra Tata, the Quechua (indigenous South American) wind god. The Huayra was named “The Hypercar of the Year 2012” by Top Gear magazine. On 11th February 2015 it was reported that the Pagani Huayra had been sold out. The Huayra was limited to just 100 units as part of Pagani’s agreement with engine supplier Mercedes-AMG. The Pagani Huayra was officially debuted online with several pictures in a press release on the 25th January 2011. The official world debut was at the headquarters of Pirelli in Milan in February 2011. The Huayra has a top speed of about 383 km/h (238 mph) and it has a 0-97 km/h (60 mph) acceleration time of 2.8 seconds. Using Pirelli tyres, the Pagani Huayra is capable of 1.66 g of lateral acceleration. The Pagani Huayra uses a seven-speed sequential gearbox and a single disc clutch. The choice not to use a dual-clutch was due to the increase in weight of over 70 kg (154 lb), thus negating any advantage of the faster gear changes in a double-clutch transmission. As a result, the transmission weighs 96 kg (212 lb). The car is equipped with Brembo brake calipers, rotors and pads. The calipers have six pistons at the front and four at the rear. The rotors are drilled carbon ceramic, 380 mm (15.0 in) in diameter and 34 mm (1.3 in) thick. The Huayra uses a 6.0 L (5,980 cc) twin-turbocharged M158 60° V12 engine developed by Mercedes-AMG specially for the Huayra, which has a power output of 740 PS (730 bhp) at 5,800 rpm and 1,000 Nm (738 lb/ft) of torque at 2,250-4,500 rpm. The engine has been designed at the request of Pagani to reduce turbo lag and improve response, achieved with smaller turbochargers, a different intercooler configuration and re-programmed ECU settings. Like many high-performance cars, the Huayra uses dry sump lubrication. This has several key benefits including guaranteeing oil flow even when the car is subjected to extreme lateral acceleration, preventing “oil surge” which allows the engine to operate more efficiently while the lack of an oil pan allows mounting the engine lower, lowering the car’s centre of gravity and improving handling. The fuel consumption of the Huayra is 10 mpg‑US (23.5 L/100 km; 12.0 mpg‑imp) in city and 14 mpg‑US (16.8 L/100 km; 16.8 mpg‑imp) in highway (EPA testing). A water/oil heat exchanger reduces engine warm-up times on cold days and helps maintain a stable temperature for refrigerants and lubricants. To minimise the use of pipes and fittings (and the overall weight of the vehicle), the coolant expansion tank is mounted directly on the engine. Intercooler fins act as an expansion tank circuit at low temperatures. The titanium exhaust system was designed and built by MHG-Fahrzeugtechnik. Hydroformed joints were developed to reduce back pressure and ensure a free flow exhaust. Titanium reduces the weight of the exhaust system while the Inconel silencers improve reliability in the most exposed parts of the exhaust at high temperatures. The entire system weighs less than 10 kg (22 lb). The Pagani Huayra is different from its predecessor in that it incorporates active aerodynamics. It is capable of changing the height of the front from the ground and independently operating four flaps placed at the rear and front of the car. The behaviour of the flaps is managed by a dedicated control unit that is fed information from systems such as the ABS and ECU, which pass on information about the car’s speed, yaw rate, lateral acceleration, steering angle and throttle position. This is intended to achieve minimal drag coefficient or maximum downforce depending on the situation. The Huayra’s designer Horacio Pagani states that it has a variable drag coefficient of between .31 and .37. The system also prevents excess body roll in the corners by raising the “inside” flaps (i.e. the left ones in a left-handed corner and vice versa), increasing the downforce on that side of the car. The rear flaps also act as an airbrake. Under hard braking, both the front suspension and the two rear flaps are raised to counter-act weight transfer to the front wheels and keep the whole car stable, for instance when entering a corner. Air from the radiator is extracted through an arch in the bonnet at an angle that is designed not to affect the streamline around the body. The side air intakes behind the front wheels create a low pressure zone, resulting in downforce. The Huayra BC is a track focused version of the Huayra which was unveiled at the 2016 Geneva Motor Show. The Huayra BC is named after the late Benny Caiola, a friend of Horacio Pagani, and the first Pagani customer. The Huayra BC has an improved version of the standard Huayra’s 6.0 L twin-turbocharged V12 engine having a power output of 764 PS (754 bhp) at 5900 rpm as well as 1,000 Nm (738 lb/ft) at 2500-5600 rpm of torque. The dry weight is reduced by 132 kg (291 lb) to just 1,218 kg (2,685 lb), thanks to the use of a new material called ‘carbon triax’ which Pagani claims is 50% lighter and 20% stronger than regular carbon fibre, giving the car a power-to-weight ratio of 1.62 kg (3.57 lb) per horsepower. The Huayra BC comes with a lighter titanium exhaust system, new aluminium alloy wheels, and a stripped out interior. The tires are Pirelli P-Zero Corsas that feature 12 different rubber compounds, and the suspension and wishbones are made of aeronautical grade aluminum, known as Avional. The Huayra BC also has a new front bumper with a front splitter and winglets, deeper side skirts, and an air diffuser that stretches the entire width of the rear bumper with a large rear wing. The car could be ordered with an optional roof scoop. All of the exterior components in the car are used to optimize downforce and drag. The Huayra BC uses an Xtrac 7-speed sequential manual transmission. Pagani has stuck with a single-clutch gearbox because it weighs 40% less than double-clutch gearboxes. Pagani planned to make 20 units of the Huayra BC, which were all sold out. In reality, Pagani drastically overproduced the Huayra BC, producing 30 units instead of the promised 20, to the irritation of some owners. After 2 years of development, the Huayra Roadster was officially unveiled at the 2017 Geneva Motor Show. The over-all appearance of the car has changed, with the most obvious being the removable top (hence the Roadster name). This part of the vehicle is also its key element. The design of the rear is also different, with new eyelid-like fixed flaps that continue with the design and eventually end on the rear lights. The rear engine cover also has a new shape to adapt to the roadster form and now has vents for efficient cooling. The wheels are unique and specifically constructed for the car. The car has conventional doors instead of the Gull-wing doors of the coupé as they are impossible to fit on an open top car while maintaining the low weight. The vehicle utilises the same twin-turbocharged M158 V12 engine as the coupé, but it now has a total power output of 764 PS (754 hp) at 6,200 rpm and 1,000 Nm (738 lb/ft) of torque at 2,400 rpm. All of this power is delivered to the rear wheels via a 7-speed automated manual transmission by Xtrac. The car now uses a hydraulic and electronic activation system with carbon synchronizers. Bosch has also contributed in the construction of the car and the car uses their ECU system. The weight is now 70 kg (154 lb) lighter, for a total of 1,280 kg (2,820 lb), making it the first roadster lighter than the coupe version. Only 100 will be made, all of which have already been sold. The tyre supplier is Pirelli, with P-Zero tyres. The tyre have a white narrow outline, resembling those of an F1 race car. Pagani has also used a new material for the Roadster called carbon triax, which is a tri-axis fiberglass meshed with carbon-fibre power bands. Pagani states that the car produces 816 kg (1,800 lb) of downforce or 1.8 lateral G-force. This figure is unproven, but if true, Pagani will have set a new record. Introduced in July 2019, the Huayra Roadster BC, often mistakenly called the Huayra BC Roadster, is the track-oriented version of the Roadster. It shares few aerodynamic parts as present on the BC and has a modified version of the 6.0-litre twin-turbocharged V12 engine rated at 802 PS (791 bhp) and 1,050 Nm (774.5 lb/ft) of torque. The 7-speed Xtrac sequential gearbox with single clutch used on the roadster is 35% lighter than a contemporary dual-clutch gearbox. The Huayra Roadster BC sits at 1,250 kg (2,756 lb) which is slightly heavier than the coupe, with a dry weight of 1,218 kg (2,685 lb). It is 30 kg (66 lb) lighter than the Huayra Roadster 1,280 kg (2,822 lb). The monocoque of the Roadster BC is constructed of carbon-titanium HP62 material to keep weight low and make the construction rigid. The Roadster BC is claimed to generate 500 kg (1,102 lb) of downforce at 280 km/h (174 mph) due to its large fixed rear wing and aerodynamic elements. In addition to movable active Aero elements, the titanium exhaust incorporates flaps in the catalytic converters to divert exhaust gases over the underfloor elements like a Formula 1 car’s blown diffuser. Production of the Huayra Roadster BC will be limited to 40 units only. Introduced in February 2020, the Imola is named after the Autodromo Internazionale Enzo e Dino Ferrari (Imola Circuit), where it underwent 16,000km of high-speed testing. It is the most powerful street-legal variant of the Huayra, using the same Mercedes-AMG V12 tuned to 838 PS (827 hp) and 1,100 Nm (811 lb/ft). Weight saving measures such as a new carbon fibre blend and lightweight paint application have reduced the Imola’s dry weight to 1,246 kg (2,747 lb). Exterior changes from the standard Huayra include a large seven-section diffuser, a large roof scoop, a shark fin, more pronounced side skirts and a wide fixed rear wing with an integrated stoplight. Six Imola were built: 5 for customers and 1 prototype for Horacio Pagani. On December 16, 2020, Pagani introduced the Huayra Tricolore, was built to celebrate the 60th Anniversary of Frecce Tricolori, Italy’s aerobatic team. The Tricolore uses a twin-turbo 6.0-liter V12 engine sourced from Mercedes-AMG which has been tuned to produce 829 horsepower and 811 pound-feet of torque, which is 38bhp and 37lb ft more than the power and torque produced by a standard Huayra BC engine. The car is only available in roadster form and shares much of the bodywork of the Roadster BC. It is unpainted except for a clear blue lacquer, and red, white, and green stripes from the nose along the top of the car’s surface. Inside, the Tricolore is equipped with white and blue leather seats with Italian flag stripes, and the Tricolori logo is embroidered into the headrests. The Pitot tube mounted on the nose of the car, a metal measuring device that’s typically uses on planes to measure air speed, is a unique feature of the Tricolore. The production is limited to three customer units as its predecessor and priced at €5,500,000+taxes ($6.7 Million+taxes) each. In reality, there will be four Huayra Tricolore: 3 customer cars and 1 prototype owned by the company. The first two customer cars have been delivered, as of early 2022. One car went to a customer in Stuttgart, Germany, while another went to a customer in Wisconsin, USA (but delivered through Pagani of Dallas). In March 2021, Pagani introduced the Huayra R, a track-only version of the Huayra and the successor of the Pagani Zonda R. The Huayra R uses the “Pagani V12-R”, a version of the 6.0 L naturally aspirated Mercedes-Benz V12 engine built from the ground up by HWA AG to produce 850 PS (838 bhp) at 8,250 rpm as well as 750 Nm (553 lb/ft) of torque at 5,500 rpm to 8300 rpm, and a redline at 9,000 rpm. The Huayra R has a 6-speed sequential transmission newly developed for the car, and various weight saving measures have resulted in a lower dry weight of 1,050 kg (2,315 lb). Pagani plans a limited 30-car production run for the Huayra R, similar to the limited 15-car production run of the track-only version of the Pagani Zonda, the Zonda R. It will cost €2.6mln + taxes (around $3.1mln + taxes). On June 16, 2022, Pagani introduced the Huayra Codalunga, a 5 units limited version of the Huayra, to pay homage to the lines of racecars from the 1960s, like the Porsche 917 (Horacio’s favorite car).[36] Prices started at €7mln+tax (around $7.36mln+tax) with all 5 units being sold before its unveiling. This car was the result of a special project by Pagani Grandi Complicazioni. On November 23, 2023, Pagani introduced the Imola Roadster, the convertible version of the Pagani Imola but inspired by the Huayra R. The Imola Roadster uses the same Mercedes-AMG V12, 6.0-liter twin-turbo engine to produce 850 PS (838 hp) at 5,600 rpm as well as 1,100 Nm (553 lb/ft) of torque from 3,600 to 5,600 rpm. Production of the Imola Roadster will be limited to 8 units only. In December 2017, Pagani introduced the Huayra Lampo in partnership with Lapo Elkann of Garage Italia Customs. The car is inspired by the Fiat Turbina concept introduced in 1954. This particular Huayra gets the ‘Tempesta’ pack too: larger front openings, plus new aero elements on the front splitter and sills. In July 2024, Pagani introduced a one-off version of the Huayra called the Huayra Epitome, which was developed by Pagani Grandi Complicazioni. It is powered by a twin-turbocharged 6.0-liter V-12 engine sourced from Mercedes-AMG that develops 852 horsepower and 811 pound-feet of torque, and revs to 6,700 rpm mated to a seven-speed manual transmission.

PONTIAC

The Pontiac GTO is a front-engine, rear-drive, two-door, and four-passenger automobile manufactured and marketed by the Pontiac division of General Motors over four generations from 1963 until 1974 in the United States — with a fifth generation made by GM’s Australian subsidiary, Holden, for the 2004 through 2006 model years. The first generation of the GTO is credited with popularizing the muscle car market segment in the 1960s. In early 1963, General Motors management banned divisions from involvement in auto racing. This decision followed the 1957 voluntary ban on automobile racing that the Automobile Manufacturers Association instituted. By the early 1960s, Pontiac’s advertising and marketing approach was heavily based on performance. With GM’s ban on factory-sponsored racing, Pontiac’s managers emphasized street performance. In his autobiography Glory Days, Pontiac chief marketing manager Jim Wangers, who worked for the division’s contract advertising and public relations agency, states that John DeLorean, Bill Collins, and Russ Gee were responsible for the GTO’s creation. It involved transforming the upcoming second-generation Pontiac Tempest (which reverted to a conventional front-engine with front transmission configuration) into a sporty car, with a larger 389 cu in (6.4 L) Pontiac V8 engine from the full-sized Pontiac Grand Prix hardtop coupe in place of the standard 326 cu in (5.3 L) V8. By promoting the big-engine option as a unique high-performance model, they could appeal to the youth market (which had also been recognized by Ford Motor Company’s Lee Iacocca, who was preparing the Ford Mustang variant of the second-generation Ford Falcon compact). The GTO disregarded GM’s policy limiting the A-body intermediate line to a maximum engine displacement of 330 cu in (5.4 L). The development team discovered a loophole in the policy that did not restrict the offering of large engines as an option. Pontiac general manager Elliot “Pete” Estes approved the new model with sales manager Frank Bridge limiting initial production to 5,000 cars. The name, GTO was inspired by the Ferrari 250 GTO. The moniker is an Italian abbreviation for Gran Turismo Omologato (“grand tourer homologated”), designating being certified by the FIA for racing in the grand tourer class as a production car with at least a hundred units made. Unusually for such a Detroit marketing ploy, a Pontiac employee had the car homologated by the FIA in 1964, so that it was indeed possible for the GTO to compete in European sports car racing. The first Pontiac GTO began production September 3, 1963, and was available as an option package for the Pontiac Tempest-based LeMans model, available in coupé, hardtop, and convertible body styles. The US$295 package included a 389 cu in (6.4 L) V8 rated at 325 hp at 4,800 rpm with a single Carter AFB four-barrel carburettor and dual exhaust pipes, chromed valve covers and air cleaner, seven-blade clutch fan, a floor-shifted three-speed manual transmission with a Hurst shifter, stiffer springs, larger diameter front sway bar, wider wheels with 7.50×14 redline tires, hood scoops, and GTO badges. Optional equipment included a four-speed manual transmission, Super Turbine 300 two-speed automatic transmission, a more powerful engine with “Tri-Power” carburetion (three two-barrel Rochester 2G carburettors) rated at 348 bhp, metallic drum brake linings, limited-slip differential, heavy-duty cooling, ride and handling package as well as a tachometer mounted in the far right dial on the dash. Some limited power features were available, as well as other accessories. With every available option, the GTO cost about $4,500 and weighed around 3,500 lb (1,600 kg). Most contemporary road tests by the automotive press, such as Car Life criticized the slow steering, particularly without power steering, and inadequate drum brakes, which were identical to those of the normal Tempest. Frank Bridge’s initial sales forecast of 5,000 units proved inaccurate: the GTO package’s total sales amounted to 32,450 units. The Tempest model lineup, including the GTO, was restyled for the 1965 model year, adding 3.1 inches (79 mm) to the overall length while retaining the same wheelbase and interior dimensions. It had Pontiac’s characteristic vertically stacked quad headlights. Overall weight was increased by about 100 lb (45 kg). The brake lining area increased by nearly 15%. Heavy-duty shocks were standard, as was a stronger front antisway bar. The dashboard design was changed, and an optional rally gauge cluster (US$86.08) added a more legible tachometer and oil pressure gauge. An additional option was a breakerless transistor ignition. The 389 cubic-inch engines received revised cylinder heads with re-cored intake passages and high-rise intake manifolds, improving airflow to the engine. Rated power increased to 335 hp at 5,000 rpm for the base four-barrel engine; the Tri-Power engine was now rated 360 hp at 5,200 rpm. The ‘S’-cammed Tri-Power engine had slightly less peak torque rating than the base engine 424 lb/ft (575 Nm) at 3,600 rpm as compared to 431 lb/ft (584 Nm) at 3,200 rpm. Transmission and axle ratio choices remained the same. The three-speed manual was standard, while two four-speed manual transmissions (wide or close ratio) and a two-speed automatic transmission were optional. The restyled car had a new simulated hood scoop. A seldom-seen dealer-installed option consisted of a metal underhood pan and gaskets to open the scoop, making it a cold air intake. The scoop was low enough that its effectiveness was questionable (it was unlikely to pick up anything but boundary layer air), but it allowed an enhanced engine sound. Another exterior change was the black “egg-crate” grille. Car Life tested a 1965 GTO with Tri-Power and what they considered the most desirable options (close-ratio four-speed manual transmission, power steering, metallic brakes, rally wheels, 4.11 limited-slip differential, and “Rally” gauge cluster), with a total sticker price of US$3,643.79. With two testers and equipment aboard, they recorded a 0–60 miles per hour (0–97 km/h) acceleration time of 5.8 seconds, the standing quarter-mile in 14.5 seconds with a trap speed of 100 miles per hour (160 km/h), and an observed top speed of 114 miles per hour (182.4 km/h) at the engine’s 6,000 rpm redline. A four-barrel Motor Trend test car, a heavier convertible handicapped by the two-speed automatic transmission and the lack of a limited-slip differential, ran 0–60 mph in 7 seconds and through the quarter-mile in 16.1 seconds at 89 miles per hour (142.4 km/h). Major criticisms of the GTO continued to center on its slow steering (ratio of 17.5:1, four turns lock-to-lock) and subpar brakes. Car Life was satisfied with the metallic brakes on its GTO, but Motor Trend and Road Test found the four-wheel drum brakes with organic linings to be alarmingly inadequate in high-speed driving. Sales of the GTO, abetted by a marketing and promotional campaign that included songs and various merchandise, more than doubled to 75,342. It spawned many imitators, both within other GM divisions and its competitors. The GTO became a separate Pontiac model (model number 242) in 1966, instead of being an “option package” on the Tempest LeMans. The entire GM “A” body intermediate line was restyled that year, gaining more curvaceous styling with kicked-up rear fender lines for a “Coke-bottle” look, and a slightly “tunneled” backlight. The tail light featured a louvered cover, only seen on the GTO. Overall length grew only fractionally, to 206.4 in (5,243 mm), still on a 115 in (2,921 mm) wheelbase, while width expanded to 74.4 in (1,890 mm). The rear track increased by one inch (2.5 cm). Overall weight remained about the same. The GTO was available as a pillared coupe, a hardtop (without B-pillars), and a convertible. An automotive industry first was a plastic front grille that replaced the pot metal and aluminum versions used in earlier years. New Strato bucket seats were introduced with higher and thinner seat backs and contoured cushions for added comfort and adjustable headrests were introduced as a new option. The instrument panel was redesigned and more integrated than in previous years with the ignition switch moved from the far left of the dash to the right of the steering wheel. Four pod instruments continued, and the GTO’s dash was highlighted by walnut veneer trim. Engine and carburettor choices remained the same as the previous year, except the Tri-Power option was discontinued mid-model year. A new engine was offered that saw few takers: the XS option consisted of a factory Ram Air set up with a new 744 high lift cam. Approximately 35 factory-installed Ram Air packages are believed to have been built, though 300 dealership-installed Ram Air packages are estimated to have been ordered. Sales increased to 96,946, the highest production figure for all GTO years. Although Pontiac had strenuously promoted the GTO in advertising as the “GTO Tiger,” it had become known in the youth market as the “goat.” The GTO underwent a few styling changes in 1967. The louver-covered taillights were replaced with eight tail lights, four on each side. Rally II wheels with colored lug nuts were also available in 1967. The GTO emblems on the fenders’ rear part were moved to the chrome rocker panels. The grille was changed from a purely split grille to one that shared some chrome. The 1967 GTO was available in three body styles:  Hardtop – 65,176 produced; Convertible – 9,517 produced; Sports coupe – 7,029 produced. The GTO also saw several mechanical changes in 1967. The Tri-Power carburetion system was replaced with a single 4-barrel Rochester Quadrajet carburetor. The 389 cu in (6.4 L) engine received a larger cylinder bore 4.12 in (104.6 mm) for a total displacement of 400 cu in (6.6 L) V8, which was available in three models: economy, standard, and high output. The economy engine used a two-barrel carburetor rather than the Rochester Quadrajet and was rated at 265 hp at 4,400 rpm and 397 lb/ft (538 Nm) at 3,400 rpm. The standard engine was rated at 335 hp at 5,000 rpm, and the highest torque of the three engines at 441 lb/ft (598 Nm) at 3,400 rpm. The high output engine produced the most power for that year at 360 hp at 5,100 rpm and a maximum torque of 438 lb⋅ft at 3,600 rpm.  Emission controls were fitted in GTOs sold in California. The 1967 model year cars required new safety equipment. A collapsible steering column with an energy-absorbing steering wheel accompanied by a padded instrument panel, non-protruding control knobs, and four-way emergency flashers became standard. A shoulder belt option was also available, and the brake master cylinder was now a dual reservoir unit with a backup hydraulic circuit. The two-speed automatic transmission was also replaced with a three-speed Turbo-Hydramatic TH-400, which was equipped with a Hurst Performance dual-gate shifter, called a “his/hers” shifter, that permitted either automatic shifting in “drive” or manual selection through the gears. Front disc brakes were also an option in 1967. The GTO sales for 1967 totalled 81,722 units.

PORSCHE

The 356 was created by Ferdinand “Ferry” Porsche (son of Dr. Ing. Ferdinand Porsche, founder of the German company), who founded the Austrian company with his sister, Louise. Like its cousin, the Volkswagen Beetle (which Ferdinand Porsche Senior had designed), the 356 was a four-cylinder, air-cooled, rear-engine, rear-wheel-drive car utilising unitised pan and body construction. The chassis was a completely new design as was the 356’s body which was designed by Porsche employee Erwin Komenda, while certain mechanical components including the engine case and some suspension components were based on and initially sourced from Volkswagen. Ferry Porsche described the thinking behind the development of the 356 in an interview with the editor of Panorama, the PCA magazine, in September 1972. “….I had always driven very speedy cars. I had an Alfa Romeo, also a BMW and others. By the end of the war I had a Volkswagen Cabriolet with a supercharged engine and that was the basic idea. I saw that if you had enough power in a small car it is nicer to drive than if you have a big car which is also overpowered. And it is more fun. On this basic idea we started the first Porsche prototype. To make the car lighter, to have an engine with more horsepower…that was the first two seater that we built in Carinthia (Gmünd)”. The first 356 was road certified in Austria on June 8, 1948, and was entered in a race in Innsbruck where it won its class. Porsche re-engineered and refined the car with a focus on performance. Fewer and fewer parts were shared between Volkswagen and Porsche as the ’50’s progressed. The early 356 automobile bodies produced at Gmünd were handcrafted in aluminium, but when production moved to Zuffenhausen, Germany in 1950, models produced there were steel-bodied. Looking back, the aluminium bodied cars from that very small company are what we now would refer to as prototypes. Porsche contracted with Reutter to build the steel bodies and eventually bought the Reutter company in 1963. The Reutter company retained the seat manufacturing part of the business and changed its name to Recaro. Little noticed at its inception, mostly by a small number of auto racing enthusiasts, the first 356s sold primarily in Austria and Germany. It took Porsche two years, starting with the first prototype in 1948, to manufacture the first 50 automobiles. By the early 1950s the 356 had gained some renown among enthusiasts on both sides of the Atlantic for its aerodynamics, handling, and excellent build quality. The class win at Le Mans in 1951 was clearly a factor.  It was always common for owners to race the car as well as drive them on the streets. They introduced the four-cam racing “Carrera” engine, a totally new design and unique to Porsche sports cars, in late 1954. Increasing success with its racing and road cars brought Porsche orders for over 10,000 units in 1964, and by the time 356 production ended in 1965 approximately 76,000 had been produced. The 356 was built in four distinct series, the original (“pre-A”), followed by the 356 A, 356 B, and then finally the 356 C. To distinguish among the major revisions of the model, 356’s are generally classified into a few major groups. 356 coupés and “cabriolets” (soft-top) built through 1955 are readily identifiable by their split (1948 to 1952) or bent (centre-creased, 1953 to 1955) windscreens. In late 1955 the 356 A appeared, with a curved windshield. The A was the first road going Porsche to offer the Carrera 4 cam engine as an option. In late 1959 the T5 356 B appeared; followed by the redesigned T6 series 356 B in 1962. The final version was the 356 C, little changed from the late T6 B cars but with disc brakes to replace the drums.

One of the rarest Porsche here – and there were literally hundreds of examples of the marque present – was this, the 914, a model born of a joint need that Porsche had for a replacement for the 912, and Volkswagen’s desire for a new range-topping sports coupe to replace the Karmann Ghia. At the time, the majority of Volkswagen’s developmental work was handled by Porsche, part of a setup that dated back to Porsche’s founding; Volkswagen needed to contract out one last project to Porsche to fulfill the contract, and decided to make this that project. Ferdinand Piëch, who was in charge of research and development at Porsche, was put in charge of the 914 project. Originally intending to sell the vehicle with a flat four-cylinder engine as a Volkswagen and with a flat six-cylinder engine as a Porsche, Porsche decided during development that having Volkswagen and Porsche models sharing the same body would be risky for business in the American market, and convinced Volkswagen to allow them to sell both versions as Porsches in North America. On March 1, 1968, the first 914 prototype was presented. However, development became complicated after the death of Volkswagen’s chairman, Heinz Nordhoff, on April 12, 1968. His successor, Kurt Lotz, was not connected with the Porsche dynasty and the verbal agreement between Volkswagen and Porsche fell apart. In Lotz’s opinion, Volkswagen had all rights to the model, and no incentive to share it with Porsche if they would not share in tooling expenses. With this decision, the price and marketing concept for the 914 had failed before series production had begun. As a result, the price of the chassis went up considerably, and the 914/6 ended up costing only a bit less than the 911T, Porsche’s next lowest price car. The 914/6 sold quite poorly while the much less expensive 914/4 became Porsche’s top seller during its model run, outselling the Porsche 911 by a wide margin with over 118,000 units sold worldwide. Volkswagen versions originally featured an 80 PS fuel-injected 1.7 L flat-4 engine based on the Volkswagen air-cooled engine. Porsche’s 914/6 variant featured a carburettor 110 PS 2.0 litre flat-6 engine from the 1969 911T, placed amidships in front of a version of the 1969 911’s “901” gearbox configured for a mid-engine car. Karmann manufactured the rolling chassis at their plant, completing Volkswagen production in-house or delivering versions to Porsche for their final assembly. 914/6 models used lower gear ratios and high brake gearing in order to try to overcome the greater weight of the 6 cylinder engine along with higher power output. Suspension, brakes, and handling were otherwise the same. A Volkswagen-Porsche joint venture, Volkswagen of America, handled export to the U.S., where both versions were badged and sold as Porsches, except in California, where they were sold in Volkswagen dealerships. The four-cylinder cars were sold as Volkswagen-Porsches at European Volkswagen dealerships. Slow sales and rising costs prompted Porsche to discontinue the 914/6 variant in 1972 after producing 3,351 of them; its place in the lineup was filled by a variant powered by a new 100 PS 2.0 litre, fuel-injected version of Volkswagen’s Type 4 engine in 1973. For 1974, the 1.7 L engine was replaced by a 85 PS 1.8 litre, and the new Bosch L-Jetronic fuel injection system was added to American units to help with emissions control. 914 production ended in 1976. The 2.0 litre flat-4 engine continued to be used in the 912E, which provided an entry-level model until the 924 was introduced.

The 911 continued to evolve throughout the 1960s and early 1970s, though changes initially were quite small. The SC appeared in the autumn of 1977, proving that any earlier plans there had been to replace the car with the front engined 924 and 928 had been shelved. The SC followed on from the Carrera 3.0 of 1967 and 1977. It had the same 3 litre engine, with a lower compression ratio and detuned to provide 180 PS . The “SC” designation was reintroduced by Porsche for the first time since the 356 SC. No Carrera versions were produced though the 930 Turbo remained at the top of the range. Porsche’s engineers felt that the weight of the extra luxury, safety and emissions equipment on these cars was blunting performance compared to the earlier, lighter cars with the same power output, so in non-US cars, power was increased to 188 PS for 1980, then finally to 204 PS. However, cars sold in the US market retained their lower-compression 180 PS engines throughout. This enabled them to be run on lower-octane fuel. In model year 1980, Porsche offered a Weissach special edition version of the 911 SC, named after the town in Germany where Porsche has their research centre. Designated M439, it was offered in two colours with the turbo whale tail & front chin spoiler, body colour-matched Fuchs alloy wheels and other convenience features as standard. 408 cars were built for North America. In 1982, a Ferry Porsche Edition was made and a total of 200 cars were sold with this cosmetic package. SCs sold in the UK could be specified with the Sport Group Package (UK) which added stiffer suspension, the rear spoiler, front rubber lip and black Fuchs wheels. In 1981 a Cabriolet concept car was shown at the Frankfurt Motor Show. Not only was the car a true convertible, but it also featured four-wheel drive, although this was dropped in the production version. The first 911 Cabriolet debuted in late 1982, as a 1983 model. This was Porsche’s first cabriolet since the 356 of the mid-1960s. It proved very popular with 4,214 sold in its introductory year, despite its premium price relative to the open-top targa. Cabriolet versions of the 911 have been offered ever since. 911 SC sales totalled 58,914 cars before the next iteration, the 3.2 Carrera, which was introduced for the 1984 model year. Coupe models outsold the Targa topped cars by a big margin.

There was an example of the 3.0 RSR here. This is a Kremer Vaillant 911 Carrera RSR, a car raced by Kremer Racing in the “Vaillant” livery, a distinctive sponsor that decorated their cars with bold, colourful designs, particularly green, white, and orange. The Kremer Racing team was a successful German racing team that specialized in modifying Porsche cars for racing, with chassis number 560-9117 being one of four such models built by Kremer for the 1975 season.

It was only really with the launch in 1989 of the 964 that a truly “new” model would appear. Designed by Benjamin Dimson in 1986, it featured significant styling revisions over previous 911 models, most prominently the more integrated bumpers. The 964 was considered to be 85% new as compared to its predecessor. The first 964s available in 1989 were all wheel drive equipped “Carrera 4” models; Porsche added the rear wheel drive Carrera 2 variant to the range in 1990. Both variants were available as a coupe, Targa or Cabriolet. The 964 Carrera was the last generation sold with the traditional removable Targa roof until the 2011 991. A new naturally aspirated engine called the M64 was used for 964 models, with a flat-6 displacement of 3.6 litres. Porsche substantially revised the suspension, replacing torsion bars with coil springs and shock absorbers. Power steering and ABS brakes were added to the 911 for the first time; both were standard. The exterior bumpers and fog lamps became flush with the car for better aerodynamics. A new electric rear spoiler raised at speeds above 50 mph and lowered down flush with the rear engine lid at lower speeds. A revised interior featured standard dual airbags beginning in 1990 for all North American production cars. A new automatic climate control system provided improved heating and cooling. Revised instrumentation housed a large set of warning lights that were tied into the car’s central warning system, alerting the driver to a possible problem or malfunction. In 1992, Porsche produced a super-lightweight, rear-wheel-drive only version of the 964 dubbed Carrera RS for the European market. It was based on Porsche’s 911 “Carrera Cup” race car and harked back to the 2.7 and 3.0 RS and RSR models. It featured a revised version of the standard engine, titled M64/03 internally, with an increased power output of 260 bhp and lightweight flywheel coupled to the G50/10 transmission with closer ratios, asymmetrical Limited Slip Differential and steel synchromesh. A track-oriented suspension system with 40 mm (1.6 in) lower ride height, stiffer springs, shocks and adjustable stabiliser bars without power steering (RHD UK cars did have power steering). A stripped-out interior devoid of power windows or seats, rear seats, air conditioning, cruise control, sound deadening or a stereo system (optionally fitted) and new racing-bucket front seats were part of the package. The front boot cover was made of aluminium and the chassis was seam welded. Wheels were made of magnesium and the glass was thinner in the doors and rear window. The Carrera RS is approximately 345 pounds (155 kg) lighter than the Carrera 2 model. Also available were a heavier Touring variant (with sound deadening, power seats (optional), undercarriage protection and power windows) and an N/GT racing variant with a stripped, blank metal interior and a roll cage. They also came with optional lights on the visors. The RS was regarded as somewhat challenging to drive, though as time has gone by, everyone seems to have warmed to it. Many were finished in some very bold colours, like this one was.

During the 1990s, Porsche was facing financial troubles and rumours of a proposed takeover were being spread. The signature air-cooled flat-6 of the 911 was reaching the limits of its potential as made evident by the 993. Stricter emissions regulations world wide further forced Porsche to think of a replacement of the air-cooled unit. In order to improve manufacturing processes, Porsche took the aid of leading Japanese car manufacturer Toyota whose consultants would assist in the overhaul of the Zuffenhausen manufacturing facility introducing mass production techniques which would allow Porsche to carry out production processes more efficiently. Porsche had realised that in order to keep the 911 in production, it would need radical changes. This led to the development of the 996. The sharing of development between the new 911 and the entry level Boxster model allowed Porsche to save development costs. This move also resulted in interchangeable parts between the two models bringing down maintenance costs. The Porsche 996 was a new design developed by Pinky Lai under Porsche design chief Harm Lagaay from 1992 to 1994; it was the first 911 that was completely redesigned, and carried over little from its predecessor as Porsche wanted the design team to design a 911 for the next millennium. Featuring an all new body work, interior, and the first water-cooled engine, the 996 replaced the 993 from which only the front suspension, rear multi-link suspension, and a 6-speed manual transmission were retained in revised form. The 996 had a drag coefficient of Cd=0.30 resulting from hours spent in the wind tunnel. The 996 is 185 mm (7 in) longer and 40 mm (2 in) wider than its predecessor. It is also 45% stiffer courtesy of a chassis formed from high-strength steel. Additionally, it is 50 kg (110 lb) lighter despite having additional radiators and coolant. All of the M96 engines offered in the 996 (except for the variants fitted to the Turbo and GT2/GT3 models) are susceptible to the Porsche Intermediate Shaft Bearing issue which can potentially cause serious engine failure if not addressed via a retrofit. The 996 was initially available in a coupé or a cabriolet (Convertible) bodystyle with rear-wheel drive, and later with four-wheel drive, utilising a 3.4 litre flat-6 engine generating a maximum power output of 296 bhp. The 996 had the same front end as the entry-level Boxster. After requests from the Carrera owners about their premium cars looking like a “lower priced car that looked just like theirs did”, Porsche redesigned the headlamps of the Carrera in 2002 similar to the high performance Turbo’s headlamps. The design for the initial “fried egg” shaped headlamps could be traced back to the 1997 911 GT1 race car. In 2000, Porsche introduced the 996 Turbo, equipped with a four-wheel-drive system and a 3.6-litre, twin-turbocharged and intercooled flat-six engine generating a maximum power output of 420 bhp, making the car capable of accelerating from 0–60 mph in 4.2 seconds. An X50 option which included larger turbochargers and intercoolers along with revised engine control software became available from the factory in 2002, increasing power output to 451 bhp. In 2005, Porsche introduced the Turbo S, which had the X50 option included as standard equipment, with the formerly optional Carbon fibre-reinforced Silicon Carbide (C/SiC) composite ceramic brakes (PCCB) also included as standard. In 2000, power output on the base Carrera model was increased to 300 bhp. 2001 marked the final year of production for the base Carrera 4 Coupé in narrow body format. In 2002, the standard Carrera models underwent the above-mentioned facelift. In addition, engine capacity was also increased to 3.6-litres across the range, yielding gains of 15 bhp for the naturally aspirated models. 2002 also marked the start of the production of the 996 based Targa model, with a sliding glass “green house” roof system as introduced on its predecessor. It also features a rear glass hatch which gave the driver access to the storage compartment. Also in 2002, the Carrera 4S model was first introduced.

The 996 was replaced with the 997 in 2005. It retains the 996’s basic profile, with an even lower 0.28 drag coefficient, but draws on the 993 for detailing. In addition, the new headlights revert to the original bug-eye design from the teardrop scheme of the 996. Its interior is also similarly revised, with strong links to the earlier 911 interiors while at the same time looking fresh and modern. The 997 shares less than a third of its parts with the outgoing 996, but is still technically similar to it. Initially, two versions of the 997 were introduced— the rear-wheel-drive Carrera and Carrera S. While the base 997 Carrera had a power output of 321 hp from its 3.6 L Flat 6, a more powerful 3.8 L 350 hp Flat 6 powers the Carrera S. Besides a more powerful engine, the Carrera S also comes standard with 19 inch “Lobster Fork” style wheels, more powerful and larger brakes (with red calipers), lowered suspension with PASM (Porsche Active Suspension Management: dynamically adjustable dampers), Xenon headlamps, and a sports steering wheel. In late 2005, Porsche introduced the all-wheel-drive versions to the 997 lineup. Carrera 4 models (both Carrera 4 and Carrera 4S) were announced as 2006 models. Both Carrera 4 models are wider than their rear-wheel-drive counterparts by 1.76 inches (32 mm) to cover wider rear tyres. The 0–100 km/h (62 mph) acceleration time for the Carrera 4S with the 350 hp engine equipped with a manual transmission was reported at 4.8 seconds. The 0–100 km/h (62 mph) acceleration for the Carrera S with the 350 hp was noted to be as fast as 4.2 seconds in a Motor Trend comparison, and Road & Track has timed it at 3.8 seconds. The 997 lineup includes both 2- and 4-wheel-drive variants, named Carrera and Carrera 4 respectively. The Targas (4 and 4S), released in November 2006, are 4-wheel-drive versions that divide the difference between the coupés and the cabriolets with their dual, sliding glass tops. The 997 received a larger air intake in the front bumper, new headlights, new rear taillights, new clean-sheet design direct fuel injection engines, and the introduction of a dual-clutch gearbox called PDK for the 2009 model year. They were also equipped with Bluetooth support. The change to the 7th generation (991) took place in the middle of the 2012 model year. A 2012 Porsche 911 can either be a 997 or a 991, depending on the month of the production.

In February 2006, Porsche unveiled the second generation of GT3, the 997 commonly now known as the 997.1 GT3. In addition to a new 415 PS 3.6 litre flat-six engine, the vehicle featured “zero lift” aerodynamics, meaning the car creates only aerodynamic downforce and no grip-diminishing “lift” upwards and away from the road surface. The GT3 made use of a modified, track oriented version of Porsche’s active PASM suspension making it the first of Porsche’s RS or GT3 versions to feature an electronically adjustable suspension system. Also available was a navigation system and Porsche’s “sports chrono” gauge package. The car went to sale in summer of 2006. A total of 917 units were sold in the United States and 46 units in Canada. The 997 GT3 has a rated 0–60 mph acceleration time of 4.1 seconds and has a top speed of 311 km/h (193 mph). Road and Track was able to achieve a 0–60 mph acceleration time of 3.8 seconds. Porsche’s official test-driver Walter Röhrl completed the Nürburgring Nordschleife in 7 minutes 42 seconds with the 997 GT3 in 2006. In 2009, Porsche launched the 2nd Generation 997 GT3 (commonly known as the 997.2 GT3), with an enlarged 3.8 litre engine rated at 435 PS. It also featured a number of new options including dynamic engine mounts and a pneumatically lifting front axle to compensate for the low ground clearance. The rear spoiler was also modified along with other parts of the bodywork. Deliveries in Europe commenced in November the same year. A total of 654 units were sold in the United States and 58 units in Canada.

The 991 introduced in 2012 is an entirely new platform, only the third since the original 911. Porsche revealed basic information on the new Carrera and Carrera S models on 23 August 2011. The Carrera is powered by a 350 hp 3.4-litre engine. The Carrera S features a 3.8-litre engine rated at 400 hp. A Power Kit (option X51) is available for the Carrera S, increasing power output to 430 hp. The new 991’s overall length grows by 56 mm (2.2 in) and wheelbase grows by 99 mm (3.9 in) (now 96.5 in.) Overhangs are trimmed and the rear axle moves rearward at roughly 76 mm (3 in) towards the engine (made possible by new 3-shaft transmissions whose output flanges are moved closer to the engine). There is a wider front track (51 mm (2 in) wider for the Carrera S). The design team for the 991 was headed by Michael Mauer. At the front, the new 991 has wide-set headlights that are more three-dimensional. The front fender peaks are a bit more prominent, and wedgy directionals now appear to float above the intakes for the twin coolant radiators. The stretched rear 3/4 view has changed the most, with a slightly more voluminous form and thin taillights capped with the protruding lip of the bodywork. The biggest and main change in the interior is the center console, inspired by the Carrera GT and adopted by the Panamera. The 991 is the first 911 to use a predominantly aluminium construction. This means that even though the car is larger than the outgoing model, it is still up to 50 kilograms (110 lb) lighter. The reduced weight and increased power means that both the Carrera and Carrera S are appreciably faster than the outgoing models. The 0–60 mph acceleration time for the manual transmission cars are 4.6 seconds for the Carrera and 4.3 seconds for the Carrera S. When equipped with the PDK transmission, the two 991 models can accelerate from 0–97 km/h in 4.4 seconds and 4.1 seconds. With the optional sports chrono package, available for the cars with the PDK transmission, the 991 Carrera can accelerate from 0–97 km/h in as little as 4.2 seconds and the Carrera S can do the same in 3.9 seconds. Apart from the reworked PDK transmission, the new 991 is also equipped with an industry-first 7-speed manual transmission. On vehicles produced in late 2012 (2013 model year) Rev Matching is available on the 7-speed manual transmission when equipped with the Sport Chrono package. Rev-Matching is a new feature with the manual transmission that blips the throttle during downshifts (if in Sport Plus mode). Also, the 7th gear cannot be engaged unless the car is already in 5th or 6th gear. One of Porsche’s primary objectives with the new model was to improve fuel economy as well as increase performance. In order to meet these objectives, Porsche introduced a number of new technologies in the 911. One of the most controversial of these is the introduction of electromechanical power steering instead of the previous hydraulic steering. This steering helps reduce fuel consumption, but some enthusiasts feel that the precise steering feedback for which the 911 is famous is reduced with the new system.[citation needed] The cars also feature an engine stop/start system that turns the engine off at red lights, as well as a coasting system that allows the engine to idle while maintaining speed on downhill gradients on highways. This allows for up to a 16% reduction in fuel consumption and emissions over the outgoing models. The new cars also have a number of technologies aimed at improving handling. The cars include a torque vectoring system (standard on the Carrera S and optional on the Carrera) which brakes the inner wheel of the car when going into turns. This helps the car to turn in quicker and with more precision. The cars also feature hydraulic engine mounts (which help reduce the inertia of the engine when going into turns) as part of the optional sports chrono package. Active suspension management is standard on the Carrera S and optional on the Carrera. This helps improve ride quality on straights while stiffening the suspension during aggressive driving. The new 991 is also equipped with a new feature called Porsche Dynamic Chassis Control (PDCC). Porsche claims that this new feature alone has shaved 4 seconds off the standard car’s lap time around the Nürburgring. PDCC helps the car corner flat and is said to improve high-speed directional stability and outright lateral body control, but according to several reviews, the car is more prone to understeer when equipped with this new technology. In January 2013, Porsche introduced the all-wheel-drive variants of the Carrera models. The ‘4’ and ‘4S’ models are distinguishable by wider tyres, marginally wider rear body-work and a red-reflector strip that sits in between the tail-lights. In terms of technology, the 4 and 4S models are equipped with an all-new variable all-wheel-drive system that sends power to the front wheels only when needed, giving the driver a sense of being in a rear-wheel-drive 911. In May 2013, Porsche announced changes to the model year 2014 911 Turbo and Turbo S models, increasing their power to 513 hp on the ‘Turbo’, and 552 hp on the ‘Turbo S’, giving them a 0–97 km/h acceleration time of 3.2 and 2.9 seconds, respectively. A rear-wheel steering system has also been incorporated on the Turbo models that steers the rear wheels in the opposite direction at low speeds or the same direction at high speeds to improve handling. During low-speed manoeuvres, this has the virtual effect of shortening the wheelbase, while at high speeds, it is virtually extending the wheelbase for higher driving stability and agility. In January 2014, Porsche introduced the new model year 2015 Targa 4 and Targa 4S models. These new models come equipped with an all-new roof technology with the original Targa design, now with an all-electric cabriolet roof along with the B-pillar and the glass ‘dome’ at the rear. In September 2015, Porsche introduced the second generation of 991 Carrera models at the Frankfurt Motor Show. Both Carrera and Carrera S models break with previous tradition by featuring a 3.0-litre turbocharged 6-cylinder boxer engine, marking the first time that a forced induction engine has been fitted to the base models within the 911 range

Porsche unveiled the facelifted 991.2 GT3 at the 2017 Geneva Motor Show. Extensive changes were made to the engine allowing for a 9,000 rpm redline from the 4.0 litre flat-six engine derived from Porsche 911 GT3 R and Cup racing cars. The engine has a power output of 500 PS (493 bhp) and 460 Nm (339 lb/ft) of torque. Porsche’s focus was on reducing internal friction to improve throttle response. Compared to the 991.1, the rear spoiler is 0.8 inch taller and located farther back to be more effective resulting in a 20% increase in downforce. There is a new front spoiler and changes to the rear suspension along with larger ram air ducts. The car generates 154 kg (340 lb) of downforce at top speed. The 991.2 GT3 brought back the choice between a manual transmission or a PDK dual clutch transmission. Performance figures include a 0-60 mph acceleration time of 3.8 seconds (3.2 seconds for the PDK version) and a quarter mile time of 11.6 seconds. The GT3 can attain a top speed of 319 km/h (198 mph).

The RS version of the 991 GT3 was launched at the 2015 Geneva Motor Show, and featured in first drive articles in the press a few weeks later, with cars reaching the UK in the summer and another series of universally positive articles duly appearing. It had very big shoes to fill, as the 997 GT3 RS model was rated by everyone lucky enough to get behind the wheel, where the combination of extra power and reduced weight made it even better to drive than the standard non-RS version of the car. A slightly different approach was taken here, with the result weighing just 10kg less than the GT3. It is based on the extra wide body of the 991 Turbo. Compared to the 991 GT3, the front wings are now equipped with louvres above the wheels and the rear wings now include Turbo-like intakes, rather than an intake below the rear wing. The roof is made from magnesium a bonnet, whilst the front wings, rear deck and rear spoiler all in carbonfibre-reinforced plastic (CFRP), the rear apron is in a new polyurethane-carbonfibre polymer and polycarbonate glazing is used for the side and rear windows. The wider body allows the RS’s axle tracks to grow, to the point where the rear track is some 72mm wider than that of a standard 3.4-litre Carrera and the tyres are the widest yet to be fitted to a road-going 911. A long-throw crankshaft made of extra-pure tempered steel delivers the 4mm of added piston stroke necessary to take the GT3’s 3.8-litre flat six out to 3996cc . The engine also uses a new induction system, breathing through the lateral air intakes of the Turbo’s body rather than through the rear deck cover like every other 911. This gives more ram-air effect for the engine and makes more power available at high speeds. It results in an output of 500 bhp and 339 lb/ft of torque. A titanium exhaust also saves weight. The suspension has been updated and retuned, with more rigid ball-jointed mountings and helper springs fitted at the rear, while Porsche’s optional carbon-ceramic brakes get a new outer friction layer. Which is to say nothing of the RS’s biggest advancement over any other 911: downforce. The rear wing makes up to 220kg of it, while the front spoiler and body profile generates up to 110kg. In both respects, that’s double the downforce of the old 997 GT3 RS 4.0.  The transmission is PDK only. The result is a 0-62 mph time of just 3.3 seconds, some 0.6 seconds quicker than the 997 GT3 RS 4.0 and 0-124 mph (0-200kmh) in 10.9 seconds. The 991 GT3 RS also comes with functions such as declutching by “paddle neutral” — comparable to pressing the clutch with a conventional manual gearbox –- and Pit Speed limiter button. As with the 991 GT3, there is rear-axle steering and Porsche Torque Vectoring Plus with fully variable rear axle differential lock. The Nürburgring Nordschleife time is 7 minutes and 20 seconds. The interior includes full bucket seats (based on the carbon seats of the 918 Spyder), carbon-fibre inserts, lightweight door handles and the Club Sport Package as standard (a bolted-on roll cage behind the front seats, preparation for a battery master switch, and a six-point safety harness for the driver and fire extinguisher with mounting bracket). Needless to say, the car was an instant sell out, even at a starting price of £131,296.

The 911 GT2 RS was officially launched by Porsche at the 2017 Goodwood Festival of Speed along with the introduction of the 911 Turbo S Exclusive Series. It is powered by a 3.8 L twin-turbocharged flat-6 engine generating a maximum power of 700 PS (690 bhp) at 7,000 rpm and 750 Nm (553 lb/ft) of torque, giving the car a power to weight ratio of 2.1 kg (4.63 lb) per horsepower and making it the most powerful 911 ever built. A Weissach package option is available. In late September 2017, the GT2 RS set a 6:47.3 lap time around the Nürburgring, which made it the fastest Porsche road car lap time recorded on the track at the time.

At the 2018 Paris Motor Show held in October on the occasion of the 70th anniversary celebration of the marque, Porsche unveiled the Speedster variant of the 991 generation for the 911, as a concept. Utilising the chassis of the GT3 and the body shell of the Carrera 4 Cabriolet, the Speedster sports a 4.0-litre naturally aspirated flat-six engine with a maximum power output of 500 PS (493 bhp) and a red-line of 9,000 rpm coupled with a 6-speed manual transmission, which is claimed to be 4 kg (9 lb) lighter than the 7-speed manual transmission found on the standard 991 models, and a titanium exhaust system. The car also features the signature “hump” shaped double bubble roof cover along with a shorter windshield frame, side window glass and the analogue roof folding mechanism retaining the “Talbot” wing mirrors and the central fuel cap from the 911 Speedster concept unveiled earlier at the Goodwood Festival of Speed harking back to its use on the 356 Speedster. Other highlights include a leather interior with perforated seats, red tinted daytime running lights, carbon fibre fenders, engine cover and hood and stone guards. Production will begin in the first half of 2019 and be limited to 1,948 units in honour of the year in which the 356 “Number 1” gained its operating license. The final production version of the Speedster was unveiled at the 2019 New York Auto Show in April and dropped the “Talbot” wing mirrors in favour of standard 991 wing mirrors and announced to be available for sale in May 2019. The engine adopted from the GT3 is equipped with individual throttle bodies and a new fuel injection system and develops 510 PS at 8,400 rpm and 470 Nm (347 lb/ft) at 6,250 rpm. The exhaust system is claimed to be 10 kg (22 lb) lighter despite the addition of two petrol particle filters. The car is equipped with carbon-ceramic brakes (PCCB) as standard, a Heritage Design Package is available as option. The Speedster was also the final edition of the 991, with only 1,948 units produced. Production of the 991 generation ended on 20 December 2019, and the final 991 model was a 991 Speedster. Porsche made 233,540 991s worldwide. The last unit of the Speedster was auctioned off in April 2020.

Also here were the latest 992-generation cars including the 911 GT3 and GT3 RS.

In February 2021, Porsche introduced the 992’s GT3 version. Like most other GT3 Porsches, it is intended for mixed usage with a more track-focused setup. It uses the same 4.0 litre naturally aspirated flat-6 as the 991.2, and producing over 510 PS (503 hp). It reaches 100 km/h (62 mph) in 3.4 seconds while the top speed is 320 km/h (199 mph). The 992 GT3 recently set a lap time at Nürburgring Nordschleife with a time of 6:55.34 minutes. Unlike the standard model, the GT3 features a large rear spoiler with larger air vents, a bigger diffuser, two large exhaust connections, bucket seats in its interior, and an optional roll cage. The GT3 uses a 7-speed PDK or a 6-speed manual instead of the 7-speed manual or 8-speed PDK used in other models.

In August 2022, Porsche unveiled the 992 GT3 RS. A further evolution of other GT3 Porsches, it represents the highest track performance of their road-legal 911 lineup. It features a dramatically improved aerodynamic profile compared to the 992 GT3, resulting in 860 kilograms-force (8.4 kN) of downforce at 285 km/h, a two-fold increase over the 991.2 GT3 RS, and 409 kilograms-force (4.01 kN) of downforce at 200 km/h. The rear wing features a static portion and an active portion, which can open and close automatically based on vehicle data, or manually with a button fitted to the steering wheel, inspired by Formula 1’s Drag Reduction Systems (DRS). Its engine produces 525 PS at 8500 rpm and 465 of Nm torque at 6300 rpm. The car has a redline of 9000 rpm (same as the GT3 done by its naturally aspirated flat-six engine). The curb weight of the car in European specification is 1450 kg, and it’s capable of achieving 100 km/h in 3.2 seconds, and 200 km/h in 10.6 seconds. The top speed stated by Porsche is 296 km/h (184 mph).[36] The GT3 RS set a 20,600m Nürburgring Nordschleife lap time of 6:44:848 minutes and a 20,832m lap time of 6:49:328 minutes. In February 2023, Porsche revealed 911 GT3 RS Carrera RS Tribute Edition. This edition is a tribute to 1973 911 Carrera RS 2.7. The car has white exterior with Python Green rims, decals and badges. Behind the RS badges on the rear wing there is a tiny green American flag. The interior is also stitched in Python Green. These were only made for US market, 150 units were produced.

In August 2023, Porsche revealed the 911 S/T to celebrate that particular model’s 60th anniversary. This version uses various parts pulled from other Porsche models, the engine being the same as what is found in the GT3 RS, and a similar body to the GT3 Touring but featuring S/T-specific carbon fenders, carbon doors, and “double-bubble” roof from the GT3 RS. Similarly to the GT3, it is offered with a six-speed manual transmission, but an automatic transmission or PDK is currently not an option (unlike the GT3 RS). Only 1,963 units will be built, and it is intended for a 2024 release. The 911 S/T’s naturally aspirated 4.0-litre flat-6 engine makes 525 PS and a total of 465 Nm (343 lb/ft) of torque at 6,300 rpm. It is also the lightest Porsche in the 992 generation at 1,404 kilograms (or 3,096 pounds), and can accelerate to 100 km/h (62 mph) in 3.7 seconds. It is rear-wheel drive, and has a top speed of 299 km/h (186 mph).

Whilst its precursor, the 924, had received largely positive reviews, it was criticised by many including Porsche enthusiasts for its Audi-sourced engine and although the Turbo model had increased performance, this model carried a high price, which caused Porsche to decide to develop the 924, as they had with generations of the 911. They re-worked the platform and a new all-alloy 2.5 litre inline-four engine, that was, in essence, half of the 928’s 5.0 litre V8, although very few parts were actually interchangeable. Not typical in luxury sports cars, the four-cylinder engine was chosen for fuel efficiency and size, because it had to be fitted from below on the Neckarsulm production line. To overcome roughness caused by the unbalanced secondary forces that are typical of four-cylinder engines, Porsche included two counter-rotating balance shafts running at twice engine speed. Invented in 1904 by British engineer Frederick Lanchester, and further developed and patented in 1975 by Mitsubishi Motors, balance shafts carry eccentric weights which produce inertial forces that balance out the unbalanced secondary forces, making a four-cylinder engine feel as smooth as a six-cylinder. The engine was factory-rated at 150 hp in its U.S. configuration. Revised bodywork with wider wheel arches, similar to that of the 924 Carrera GT, a fresh interior and upgrades to the braking and suspension systems rounded out the major changes and Porsche introduced the car as the  944 in 1982. It was slightly faster (despite having a poorer drag co-efficient than the 924), the 944 was better equipped and more refined than the 924; it had better handling and stopping power, and was more comfortable to drive. The factory-claimed 0-60 mph time of less than 9 seconds and a top speed of  130 mph which turned out to be somewhat pessimistic,  In mid-1985, the 944 underwent its first significant changes. These included : a new dash and door panels, embedded radio antenna, upgraded alternator, increased oil sump capacity, new front and rear cast alloy control arms and semi-trailing arms, larger fuel tank, optional heated and powered seats, Porsche HiFi sound system, and revisions in the mounting of the transaxle to reduce noise and vibration. The “cookie cutter” style wheels used in the early 944s were upgraded to new “phone dial” style wheels (Fuchs wheels remained an option). 1985 model year cars incorporating these changes are sometimes referred to as “1985B”, “85.5” or “1985½” cars. For the 1987 model year, the 944 Motronic DME was updated, and newly incorporated anti-lock braking and air bags. Because of the ABS system, the wheel offset changed and Fuchs wheels were no longer an option. In early 1989 before the release of the 944S2, Porsche upgraded the 944 from the 2.5 to a 2.7 litre engine, with a rated 162 hp and a significant increase in torque. For the 1985 model year, Porsche introduced the 944 Turbo, known internally as the 951. This had a turbocharged and intercooled version of the standard car’s engine that produced 220 PS at 6000 rpm. In 1987, Car and Driver tested the 944 Turbo and achieved a 0-60 mph time of 5.9 seconds. The Turbo was the first car using a ceramic port liner to retain exhaust gas temperature and new forged pistons and was also the first vehicle to produce identical power output with or without a catalytic converter. The Turbo also featured several other changes, such as improved aerodynamics, notably an integrated front bumper. This featured the widest turn signals (indicators) fitted to any production car, a strengthened gearbox with a different final drive ratio, standard external oil coolers for both the engine and transmission, standard 16 inch wheels (optional forged Fuchs wheels), and a slightly stiffer suspension (progressive springs) to handle the extra weight. The Turbo’s front and rear brakes were borrowed from the Porsche 911, with Brembo 4-piston fixed calipers and 12-inch discs as ABS also came standard. Engine component revisions, more than thirty in all, were made to the 951 to compensate for increased internal loads and heat. Changes occurred for the 1987 model year. On the interior, the 1987 944 Turbo for North America became the first production car in the world to be equipped with driver and passenger side air bags as standard equipment. A low oil level light was added to the dash as well as a 180 mph (290 km/h) speedometer as opposed to the 170 mph speedometer on the 1986 model Turbos. Also included is the deletion of the transmission oil cooler, and a change in suspension control arms to reduce the car’s scrub radius. The engine remained the same M44/51 as in the 1986 model. In 1988, Porsche introduced the Turbo S. The 944 Turbo S had a more powerful engine (designation number M44/52) with 250 hp and 258 lb·ft torque (standard 944 Turbo 220 hp and 243 lb·ft. This higher output was achieved by using a larger K26-8 turbine housing and revised engine mapping which allowed maintaining maximum boost until 5800 rpm, compared to the standard 944 Turbo the boost would decrease from 1.75 bar at 3000 rpm to 1.52 bar at 5800 rpm. Top speed was factory rated at 162 mph. The 944 Turbo S’s suspension had the “M030” option consisting of Koni adjustable shocks front and rear, with ride height adjusting threaded collars on the front struts, progressive rate springs, larger hollow rear anti-roll/torsion bars, harder durometer suspension bushings, larger hollow anti-roll/torsion bars at the front, and chassis stiffening brackets in the front frame rails. The air conditioning dryer lines are routed so as to clear the front frame brace on the driver’s side. The 944 Turbo S wheels, known as the Club Sport design, were 16-inch Fuchs forged and flat-dished, similar to the Design 90 wheel. Wheel widths were 7 inches in the front, and 9 inches in the rear with 2.047 in offset; sizes of the Z-rated tyres were 225/50 in the front and 245/45 in the rear. The front and rear fender edges were rolled to accommodate the larger wheels. The manual transmission featured a higher friction clutch disc setup, an external cooler, and a limited slip differential with a 40% lockup setting. The Turbo S front brakes were borrowed from the Porsche 928 S4, with larger Brembo GT 4-piston fixed calipers and 12-inch discs; rear Brembo brakes remained the same as a standard Turbo. ABS also came standard. The 944 Turbo S interior featured power seats for both driver and passenger, where the majority of the factory-built Turbo S models sported a “Burgundy plaid” (Silver Rose edition) but other interior/exterior colours were available. A 10-speaker sound system and equalizer + amp was a common option with the Turbo S and S/SE prototypes. Only the earlier 1986, 250 bhp prototypes featured a “special wishes custom interior” options package. In 1989 and later production, the ‘S’ designation was dropped from the 944 Turbo S, and all 944 Turbos featured the Turbo S enhancements as standard, however the “M030” suspension and the Club Sport wheels were not part of that standard. The 944 Turbo S was the fastest production four cylinder car of its time. For the 1987 model year, the 944S “Super” was introduced, featuring a high performance normally aspirated, dual-overhead-cam 16-valve 190 PS version of the 2.5 litre engine (M44/40) featuring a self-adjusting timing belt tensioner. This marked the first use of four-valve-per-cylinder heads and DOHC in the 944 series, derived from the 928 S4 featuring a redesigned camshaft drive, a magnesium intake tract/passages, magnesium valve cover, larger capacity oil sump, and revised exhaust system. The alternator capacity was 115 amps. The wheel bearings were also strengthened and the brake servo action was made more powerful. Floating 944 calipers were standard, but the rear wheel brake circuit pressure regulator from the 944 turbo was used. Small ’16 Ventiler’ script badges were added on the sides in front of the body protection mouldings. Performance was quoted as 0 – 100 km/h in 6.5 seconds and a 144 mph top speed due to a 2857 lb weight. It also featured an improved programmed Bosch Digital Motronic 2 Computer/DME with dual knock sensors for improved fuel performance for the higher 10.9:1 compression ratio cylinder head. Like the 944 Turbo, the 944S received progressive springs for greater handling, Larger front and rear anti-roll bars, revised transmission and gearing to better suit the 2.5 litre DOHC higher 6800 rpm rev limit. Dual safety air bags, limited-slip differential, and ABS braking system were optional on the 944S. A Club Sport touring package (M637) was available as was the lightweight 16 inch CS/Sport Fuch 16×7 and 16×9 forged alloy wheels. This SC version car was raced in Canada, Europe and in the U.S. IMSA Firehawk Cup Series. Production was only during 1987 and 1988. It was superseded in 1989 by the ‘S2’ 944 edition. The 1987 944S power-to-weight ratio was such that it was able to accelerate from 0 to 62 mph in 6.5 seconds thus matching the acceleration of its newer larger displacement 3.0 litre 944 S2 sibling. In 1989 the 944S2 was introduced, powered by a 211 PS normally aspirated, dual-overhead-cam 16-valve 3.0 litre version of the 944S engine, the largest production 4-cylinder engine of its time. The 944S2 also received a revised transmission and gearing to better suit the 3.0 litre M44/41 powerplant. The 944S2 had the same rounded nose and a rear valance found on the Turbo model. This was the first example of the use of an integrated front bumper, where the fender and hood profiles would merge smoothly with the bumper, a design feature that has only now seen widespread adoption on the 1990 onward production cars. Performance was quoted as 0-60 mph in 6.0 seconds with a top speed of 240 km/h (150 mph) via manual transmission. A Club Sport touring package (M637) was also available. Dual air bags (left hand drive models), limited-slip differential and ABS were optional. Series 90 16-inch cast alloy wheels were standard equipment. In 1989, Porsche released the 944 S2 Cabriolet, a first for the 944 line that featured the cabriolet body built by ASC-American Sunroof Company at Weinsberg Germany. The first year of production included sixteen 944 S2 Cabriolet for the U.S. market. For the 1990 model year, Porsche produced 3,938 944 S2 Cabriolets for all markets including right-hand drive units for the United Kingdom, Australia and South Africa. This car was raced, including the British championship that was called the Porsche Motorsport Championship. Production was during 1989, 1990, and 1991. The 944 S2 power-to-weight ratio was such that it was able to accelerate from 0 to 60 mph in 6.5 seconds. In February 1991, Porsche released the 944 Turbo Cabriolet, which combined the Turbo S’s 250 hp engine with the cabriolet body built by ASC-American Sunroof Company at Weinsberg Germany. Porsche initially announced that 600 would be made; ultimately 625 were built, 100 of which were right-hand drive for the United Kingdom, Japanese, Australian, and South African market. None were imported to the U.S. and The Americas. In early 1990, Porsche engineers began working on what they had intended to be the third evolution of the 944, the S3. As they progressed with the development process, they realised that so many parts were being changed that they had produced an almost entirely new vehicle. Porsche consequently shifted development from the 944 S/S2 to the car that would replace the 944 entirely, the 968. The 944’s final year of production was 1991. A grand total 163,192 cars in the 944 family were produced between 1982 and 1991. This made it the most successful car line in Porsche’s history until the introductions of the Boxster and 997 Carrera.

There were also plenty of examples of the larger and long-running 928 model. The first V8 engined Porsche, it was originally conceived to replace the 911, though as we all know, that did not happen, with the two complementing each other in the range during the 18 year life of the 928. By the late 1960s, Porsche had changed significantly as a company, and executives including owner Ferdinand Porsche were toying with the idea of adding a luxury touring car to the line-up. Managing Director Ernst Fuhrmann was also pressuring Ferdinand to approve development of the new model in light of concerns that the current flagship model at the time, the 911, was quickly reaching the limits of its potential. Slumping sales of the 911 seemed to confirm that the model was approaching the end of its economic life cycle. Fuhrmann envisioned the new range-topping model as being the best possible combination of a sports coupe and a luxury sedan, something well equipped and comfortable enough to be easily driven over long distances that also had the power, poise and handling prowess necessary to be driven like a sports car. This set it apart from the 911, which was intended to be an out-and-out sports car. Ordered by Ferdinand Porsche to come up with a production-feasible concept for his new model, Fuhrmann initiated a design study in 1971, eventually taking from the process the final specification for the 928. Several drivetrain layouts were considered during early development, including rear and mid-engined designs, but most were dismissed because of technical and/or legislative difficulties. Having the engine, transmission, catalytic converter(s) and exhaust all cramped into a small rear engine bay made emission and noise control more difficult, something Porsche was already facing problems with on the 911 and wanted to avoid. After deciding that the mid-engine layout didn’t allow enough room in the passenger compartment, a front engine/rear wheel drive layout was chosen. Porsche also may have feared that the U.S. government would soon ban the sale of rear-engined cars in response to the consumer concern over safety problems with the rear-engined Chevrolet Corvair. Porsche engineers wanted a large-displacement engine to power the 928, and prototype units were built with a 5-litre V8 producing close to 300 hp. Ferdinand Piëch wanted this car to use a 4.6-litre V10 based upon Audi’s five-cylinder engine. Several members of the Porsche board objected, chiefly because they wished for Porsche AG to maintain some separation from Volkswagen. The first two running prototypes of Porsche’s M28 V8 used one four-barrel carburettor, but this was just for initial testing. The cars were sold with the planned Bosch K-Jetronic fuel injection system. When increasing concern within the company over the pricing and availability of fuel during the oil crisis of the 1970s became an issue of contention, smaller engines were considered in the interest of fuel economy. A push began for the development of a 3.3 litre 180 hp powerplant they had drawn up designs for, but company engineers balked at this suggestion. Both sides finally settled on a 4.5 litre SOHC per bank 16-valve V8 producing 240 PS which they considered to have an acceptable compromise of performance and fuel economy. The finished car debuted at the 1977 Geneva Motor Show, going on sale later that year. Although it won early acclaim for its comfort and power, sales were slow. Base prices were much higher than that of the 911 model and the 928’s front-engined, water-cooled design put off many Porsche purists, not least because the design marked a major change in direction for Porsche started with the introduction of the Porsche 924 in 1976 which purists found hard to accept. Porsche utilised a transaxle in the 928 to help achieve 50/50 front/rear weight distribution, aiding the car’s balance. Although it weighed more than the difficult-to-handle 911, its more neutral weight balance and higher power output gave it similar performance on the track. The 928 was regarded as the more relaxing car to drive at the time. It came with either a five-speed dog leg manual transmission, or a Mercedes-Benz-derived automatic transmission, originally with three speeds, with four-speed from 1983 in North America and 1984 in other markets. More than 80% had the automatic transmission. Exact percentage of manual gearbox cars for entire production run is not known but it is believed to be between 15 and 20%. The body, styled by Wolfgang Möbius under guidance of Anatole Lapine, was mainly galvanised steel, but the doors, front fenders, and hood were aluminium in order to make the car more lightweight. It had a substantial luggage area accessed via a large hatchback. The new polyurethane elastic bumpers were integrated into the nose and tail and covered in body-coloured plastic; an unusual feature for the time that aided the car visually and reduced its drag. Porsche opted not to offer a convertible variant but several aftermarket modifiers offered convertible conversions, most notably Carelli, based in Orange County, CA. The Carelli conversions were sold as complete cars, with the conversion doubling the price of the car. A reported 12 units were made. The 928 qualified as a 2+2, having two small seats in the rear. Both rear seats could be folded down to enlarge the luggage area, and both the front and rear seats had sun visors for occupants. The rear seats are small (due to the prominent transmission hump) and have very little leg room; they are only suitable for adults on very short trips or children. The 928 was also the first vehicle in which the instrument cluster moved along with the adjustable steering wheel in order to maintain maximum instrument visibility. The 928 included several other innovations such as the “Weissach Axle”, a simple rear-wheel steering system that provides passive rear-wheel steering to increase stability while braking during a turn, and an unsleeved, silicon alloy engine block made of aluminium, which reduced weight and provided a highly durable cylinder bore. Porsche’s design and development efforts paid off during the 1978 European Car of the Year, where the 928 won ahead of the BMW 7 Series, and the Ford Granada. The 928 is the only sports car ever to have won this competition, which is regarded as proof of how advanced the 928 was, compared to its contemporaries. Porsche introduced a refreshed 928 S into the European market in 1980 model year. Externally, the S wore new front and rear spoilers and sported wider wheels and tyres than the older variant, but the main change for the 928 S was under the bonnet where a revised 4.7 litre engine was used. European versions debuted with 300 PS, and were upgraded to 310 PS for 1984, though it is rumoured that they typically made around 330 hp. From 1984 to 1986, the S model was called S2 in UK. These cars used Bosch LH-Jetronic fuel injection and purely electronic Bosch ignition, the same systems used on the later 32-valve cars, though without the pollution controls. North American-spec 1983 and 1984 S models used, among other differences, smaller valves, milder camshafts, smaller diameter intake manifolds, and additional pollution equipment in order to meet emissions regulations, and were limited to 234 hp as a result. Due to low grade fuel 16V low compression S engine was made for Australian market in 1985 model year. It had 9.3:1 compression ratio pistons instead of normal 10.4:1 but used same large intake, high lift cams, large valves etc. of other S engines. In 1982, two special models were available for different markets. 202 “Weissach Edition” cars were sold in North America. Unusual features were champagne gold metallic paint, matching brushed gold flat disc wheels, two-tone leather interior, a plaque containing the production number on the dash and the extremely collectible three-piece Porsche luggage set. It’s believed these cars were not made with S spoilers even though these were available in U.S. during this time period as part of the “Competition Group” option. The “Weissach Edition” option was also available for the US market 911 in 1980 model year and 924 in 1981 model year. 141 special “50th Jubilee” 928 S models were available outside the U.S. and Canada to celebrate the company’s 50-year existence as a car manufacturer. This model is also sometimes referred to as the “Ferry Porsche Edition” because his signature was embroidered into the front seats. It was painted meteor metallic and fitted with flat disc wheels, wine red leather and special striped fabric seat centres. Similar 911 and 924 specials were also made for world markets. Porsche updated the North American 928 S for 1985, replacing the 4.7 litre SOHC engine with a new 5.0 litre DOHC unit sporting four valves per cylinder and producing 288 hp. Seats were also updated to a new style, these cars are sometimes unofficially called S3 to distinguish them from 16-valve “S” models. European models kept a 4.7 litre engine, which was somewhat more powerful as standard, though lower 9.3:1 compression 32-valve engine together with catalytic converters became an option in some European countries and Australia for 1986. In 1986, revised suspension settings, larger brakes with 4-piston calipers and modified exhaust was installed on the 928S, marking the final changes to old body style cars. These were straight from the 928S4, which was slated to debut a few months later. These changes came starting from VIN 1001, which means that the first thousand ’86’s had the old brakes, but later cars had the later systems. This later 1986 model is sometimes referred to as a 19861⁄2 or 1986.5 because of these changes. The name is a little misleading as more than 3/4 of the 1986 production had these updates. The 928 S4 variant debuted in the second half of 1986 with an updated version of the 5.0 litre V8 producing 320 PS, sporting a new single-disc clutch in manual gearbox cars, larger torque converter in automatics and fairly significant styling updates which gave the car a cleaner, sleeker look. S4 was much closer to being a truly world car than previous models as only major differences for North American models were instrumentation in either kilometers or miles, lighting, front and rear bumper shocks and the availability of catalytic converters in many other markets. The Australian market version was only one with different horsepower rating at 300 PS due to preparation for possible low grade fuel. Even this was achieved without engine changes. A Club Sport variant which was up to 100 kg (220 lb) lighter became available to continental Europe and U.S. in 1988. This model was watered down version of the 1987 factory prototype which had a lightened body. Also in 1987 the factory made four white lightened manual gearbox S4 models for racecar drivers who were on their payroll at the time. These were close to same as later actual Club Sport models and can also be considered prototypes for it. An SE (sometimes called the S4 Sport due to model designation on rear bumper), a sort of halfway point between a normally equipped S4 and the more race-oriented Club Sport, became available to the UK. It’s generally believed these Porsche Motorsport-engined cars have more hp than the S4. They utilise parts which later became known as GT pistons, cams and engine ECU programs. Some of them had stronger, short geared manual gearbox. The automatic gearbox was not available. For the 1989 model year, a visible change inside was digital trip computer in dashboard. At the same time Australian models received the same 320 PS engine management setup as other markets. Porsche debuted the 928 GT in the late winter 1988/89 after dropping the slowly selling CS and SE. In terms of equipment, the GT was like the 928 SE, having more equipment than a Club Sport model but less than a 928 S4 to keep the weight down somewhat. It had the ZF 40% limited-slip differential as standard like the Club Sport and SE before it. Also like the CS and SE, the GT was only available with a manual gearbox. European 1989 CS and GT wheels had an RDK tyre pressure monitoring system as standard, which was also optional for the same year S4. For 1990 model year Porsche made RDK and a 0-100% variable ratio limited-slip called PSD (Porsche SperrDifferential) standard in both GT and S4 models for all markets. This system is much like the one from the 959 and gives the vehicle even more grip. In 1990 the S4 was no longer available with a manual gearbox. The S4 and GT variants were both cut at the end of 1991 model year, making way for the final version of the 928. The 928 GTS came for sale in late 1991. Changed bodywork, larger front brakes and a new, more powerful 5.4 litre 350 PS engine were the big advertised changes; what Porsche wasn’t advertising was the price. Loaded GTS models could eclipse US$100,000 in 1995, making them among the most expensive cars on the road at the time. This severely hampered sales despite the model’s high competency and long standard equipment list. Porsche discontinued the GTS model that year after shipping only 77 of them to the United States. Total worldwide production of 928s over an 18 year period was a little over 61,000 cars. Second-hand models’ value decreased as a result of generally high maintenance costs due largely to spare parts that are expensive to manufacture, with the result that there are fewer survivors than you might expect, though with values hardening, people are now spending the money required to restore these cars.

The commercially very significant Boxster was also represented here. Grant Larson’s design, inspired by the 356 Cabriolet, Speedster, and 550 Spyder, stimulated a commercial turnaround for Porsche. Through consultation with Toyota. Porsche began widely sharing parts among models and slashed costs. By October 1991 following a visit to the Tokyo Motor Show, Porsche in dire straits, began to devise solutions to succeed the poor selling 928 and incoming 968 (a heavy update of the 944). In February 1992, Porsche began development of a successor to the 928 (mildly updated for 1992) and recently released 968. By June 1992, out of 4 proposals based on dual collaboration between the 986 and 996 (993 successor) design teams, a proposal by Grant Larson and Pinky Lai was chosen by Harm Lagaay. In August 1992, a decision was made to develop the concept into a show vehicle, in time for the 1993 North American International Auto Show. After garnering widespread acclaim from the press and public upon presentation of the Boxster Concept in January 1993, the final production 986 production exterior design by Larson was frozen in March 1993. However, by the second half of 1993, difficulties arose with fitment of some components, resulting in lengthening of the hood and requiring another design freeze by fourth quarter of that year. Prototypes in 968 bodies were built to test the mid-engine power train of the 986 by the end of 1993, with proper prototypes surfacing in 1994. Pilot production began in the second half of 1995, ahead of series production in mid-1996. The Boxster was released ahead of the 996. The 986 Boxster had the same bonnet, front wings, headlights, interior and engine architecture as the 996. All 986 and 987 Boxsters use the M96, a water-cooled, horizontally opposed (“flat”), six-cylinder engine. It was Porsche’s first water-cooled non-front engine. In the Boxster, it is placed in a mid-engine layout, while in the 911, the classic rear-engine layout was used. The mid-engine layout provides a low center of gravity, a near-perfect weight distribution, and neutral handling. The engines had a number of failures, resulting in cracked or slipped cylinder liners, which were resolved by a minor redesign and better control of the casting process in late 1999. A failure for these early engines was a spate of porous engine blocks, as the manufacturer had difficulty in the casting process. In addition to causing problems with coolant and oil systems mingling fluids, it also resulted in Porsche’s decision to repair faulty engines by boring out the cast sleeves on the cylinders where defects were noted in production and inserting new sleeves rather than scrapping the engine block. Normally, the cylinder walls are cast at the same time as the rest of the engine, this being the reason for adopting the casting technology. The model received a minor facelift in 2002. The plastic rear window was replaced by a smaller glass window. The interior received a glove compartment, new electro-mechanical hood and trunk release mechanism (with an electronic emergency release in the fuse box panel) and an updated steering wheel. Porsche installed a reworked exhaust pipe and air intake. In addition, the front headlight’s amber indicators were replaced with clear indicators. The rear light cluster was also changed with translucent grey turn signals replacing the amber ones. The side marker lights on the front wings were changed as well from amber to clear, except on American market cars where they remained amber. The bumpers were also changed slightly for a more defined, chiselled appearance, and new wheel designs were made available. The second generation of the Boxster debuted at the 2004 Paris Motor Show

On 5 November 2009, Porsche officially announced a new variant of the Boxster, which was officially unveiled at the 2009 Los Angeles Motor Show. Positioned above the Boxster S, the Boxster Spyder was the lightest Porsche on the market at the time, weighing 1,275 kg (2,811 lb), 80 kg (176 lb) lighter than a Boxster S. This was achieved through the elimination of the conventional soft top’s operating mechanism, the radio/PCM unit, door handles, air conditioning, storage compartments, cup holders and large LED light modules on the front fascia, although some of these could be re-added to the car in the form of options. Weight saving was also gained using aluminum doors, an aluminum rear deck and the lightest 19-inch wheels in the Porsche pallet. The Spyder has a firmer suspension setup than the other Boxster models, and is almost one inch lower in order to have improved handling. A manually operated canvas top, carbon fibre sports bucket seats and two signature humps running along the back of the vehicle provide characteristic design elements. It is powered by a six-cylinder boxer engine rated at 320 PS and 273 lb/ft (370 Nm) of torque, a 10 bhp increase in power over the Boxster S and the related Cayman S. The Boxster Spyder came with a 6-speed manual transmission as standard and had Porsche’s 7-speed PDK dual-clutch gearbox available as an option. The vehicle was released worldwide in February 2010 as a 2011 model.

The third-generation Boxster (internally known as the 981) was announced on 13 March 2012 at the Geneva Motor Show with sales starting in early summer 2012. The 981 Boxster reflected the new design language from the 911 (991) and 918, and featured new and revised engine and transmission specifications. Together with a new body, the type 981 Boxster featured a new, 40 per cent more torsionally rigid chassis, the front track was 40 mm (1.6 in) wider, the rear 18 mm (0.7 in) wider and the wheelbase extended by 60 mm (2.4 in), but with a small weight reduction of up to 35 kg (77 lb) compared to the previous type 987 Boxster. The standard Boxster was fitted with a new 2.7-litre flat-6 engine, and the Boxster S was fitted with the existing 3.4-litre engine but with revised performance. Both engines were equipped with a 6-speed manual gearbox and an optional 7-speed reworked PDK. Both manual and automatic models were available with several technical options, including Porsche Torque Vectoring (PTV) and a Sport Chrono Package that included active transmission mounts, and made the PDK-equipped model even faster. Porsche claimed that the new generation Boxster provided fuel savings of 15% over the outgoing model. The range was expanded in March 2014 with the addition of the GTS derivative, with slightly altered front and rear bumpers and an additional 15 PS/ 15 bhp from the 3.4-litre engine. In 2015 the GT4 derivative was introduced, seeing the engine from a 991.1 Carrera S rotated 180 degrees. The GT4 also saw a lowered ride height, altered bumpers, a rear wing and additional GT package upgrades including brakes and certain suspension components from a 991.1 GT3. These special cars were manufactured from 2015 – 2016 with a total of 2500 being made, making this model one of the more desirable collector’s cars in Porsche’s lineup. The GT4 was widely considered one of the best cars of 2015/2016 where it won many awards for its impeccable handling and performance. The third generation Cayman was unveiled at the 2012 Geneva Motor Show. The production version of the 981 Cayman was released as a 2014 model in the spring of 2013. The new car was available in both the standard trim with a 2.7-litre engine, and in the S trim with a 3.4-litre engine. Both versions were available with either a 6-speed manual or a dual-clutch 7-speed PDK transmission. The 981 Cayman featured upgrades including a new body, a longer wheelbase, a wider front track, electrically powered steering, and a redesigned interior that matched the firm’s contemporaneous 911 models. The new model gained acclaim in the motoring press as one of the best handling sports cars at any price, due to its mid-engine layout and driving dynamics. The Cayman S benefited from the same engine and running gear as Porsche’s 3.4-litre version of the 911. A heavily revamped version of both models, known as the 982 generation was launched in 2016 to replace these cars.

Much rumoured for some time, the Cayman GT4 was officially launched at the 2015 Geneva Show, positioned to sit between the Cayman GTS and the 911 GT3. By the time of the official unveiling, the car was supposedly sold out many times over, though more recently it has become apparent that at least some Porsche dealers have been holding onto cars claiming that the first purchaser changed their mind, and then offering them to those who did not get one of the allocation a year ago, at vastly inflated prices. If true, this is very sharp practice indeed, but seems to be the sort to tricks that are becoming increasingly common as enthusiasts are being fleeced in the name of extra profit. For a starting price of around £65,000 in the UK, the lucky customer would get a car which used used a stiffened and strengthened Cayman bodyshell as a starting point, but lowered by 30mm . Porsche say that in fitting as many GT parts as possible, they did not  make it out of a Cayman GTS, but rather they produced an entry-level mid-engined GT3 car. That sounds like PR spin to me, as of course the car does use an awful lot of parts from the regular Cayman. However, plenty is changed, too. There is a reworked version of the Carrera S’s 3.8-litre flat six engine, producing  380bhp at 7400rpm and 310lb ft at 4750-6000rpm, hooked up to a modified version of the Cayman GTS’s six-speed manual gearbox. A PDK dual-clutch automatic was considered but rejected, meaning the Cayman GT4 is manual only. This is enough to mean that the 0-62mph sprint takes 4.4sec and the top speed is 183mph, with combined fuel economy of 27.4mpg and CO2 emissions rated at 238g/km. The front axle and suspension are borrowed from the 911 GT3 and the rear axle and forged aluminium double wishbone suspension are completely new. Dampers are taken from the 911 GT3. The electric steering system from the 911 GT3 does make it onto the Cayman GT4 but is given new software. Stopping power is provided by standard steel brakes, or optional carbon-ceramics from the 911 GT3. The forged 20in alloy wheels were new and are shod with Michelin Pilot Sport Cup 2 tyres. The rear 295/30 ZR20 tyres are bespoke, but the front 245/35 ZR20s were borrowed from the 911 GT3 as they were “a perfect match”. design-wise, the goal was to create a “zero lift car”, but thanks to the extensive aerodynamic and cooling package on the car – which includes a front splitter, a larger front grille and increased frontal air intakes, side air intakes, not one but two rear spoilers and a fully functional diffuser – the Cayman GT4 produces as much downforce at speed (100kg) as the 911 GT3. Every single part on the Cayman GT4 has a functional use. Other design features include  “cool” black glass on the front and rear lights, blackened twin central exhausts and quality stitching on the twin lightweight bucket seats, taken from the 918 Spyder, as small details adding to that ‘want factor’.Despite all the extra equipment, the Cayman GT4 weighs no more than a Cayman GTS, tipping the scales at 1340kg dry. You could delete items such as the sat-nav and air-con to save weight, but few customers did, just as with the 911 GT3 RS were just 2% of buyers deleted the air-con. Inside, the steering wheel was new. The sports seats were trimmed in both leather and Alcantara. Standard equipment included bi-xenon headlights, a sports exhaust system, a Sport Chrono Package with dynamic engine mounts, the Porsche Torque Vectoring system, a mechanical limited-slip differential at the rear and the Porsche Stability Management system. On the options list were items such as carbonfibre-reinforced, plastic-backed seats for the two-seat interior. These weigh just 15kg each and were inspired by the 918 Spyder. A customised version of the Sport Chrono Package was offered, as is a Club Sport Package. Initially it was declared that production would be very limited, but Porsche soon relented and far more were built than had originally been declared.

The 718 Cayman GT4 and 718 Spyder (previously named the Boxster Spyder) were revealed in June 2019. Both are differentiated from less powerful models by more aggressive bodywork, including a lower stance, new front bumper, a large new diffuser, and exhaust pipes that are spaced farther apart. The GT4 also features larger side intakes and an adjustable wing, the latter of which helps it generate up to 150 kg (330 lb) of downforce, 50 percent more than its predecessor. Both have a naturally aspirated 4.0-litre flat-6 derived from the 992’s 3.0-litre 9A2EVO engine, which is rated at 414 bhp at 7,600 rpm and 420 Nm (310 lb/ft) of torque at 5,000–6,800 rpm. The engine has cylinder deactivation, a first for Porsche. Porsche claims a top speed of 304 km/h (189 mph) for the GT4, and 301 km/h (187 mph) for the Spyder. The front suspension and brakes are borrowed from the 911 GT3, and the adaptive dampers, ABS and stability-control programming are borrowed from the 911 GT3 RS. The anti-roll bar end links, camber and toe can be manually adjusted, but the ride height–3 cm (1.2 in) lower than a standard 718–is fixed. Both are around 15 kg heavier than the GTS models. Sales commenced in the spring of 2020. For the 2021 model year, the GT4 and Spyder became available with the 7-speed PDK dual-clutch transmission as an option. It reduces the 0-60 mph (97 km/h) acceleration time from 4.3 seconds to 3.7 seconds. In March of 2023, Porsche announced that 718 GT4 and Spyder Models would cease production as of the 2024 model year, however it was later extended through the 2025 model year with production ending October 2025.

In 2021, Porsche unveiled the 718 Cayman GT4 RS, the first Cayman to receive the RS treatment which is usually reserved for the 911 models. With a 4.0 naturally aspirated flat-six derived from the 911 GT3, it puts out 500 PS (490 bhp) and 450 Nm (330 lb/ft) with an rpm limit of 9,000rpm, which allows it to sprint from 0–100 km/h (0–62 mph) in just 3.4 seconds. It generates 25% more downforce than the GT4 variant, through a swan-neck attachment fixed rear wing. The GT4 RS lapped the Nürburgring Nordschleife 23 seconds faster than the GT4. There is a hefty price premium over the GT4 model.

The 918 Spyder was first shown as a concept at the 80th Geneva Motor Show in March 2010. On 28 July 2010, after 2,000 declarations of interest, the supervisory board of Porsche AG approved series development of the 918 Spyder. The production version was unveiled at the September 2013 Frankfurt Motor Show. Porsche also unveiled the RSR racing variant of the 918 at the 2011 North American International Auto Show, which combines hybrid technology first used in the 997 GT3 R Hybrid, with styling from the 918 Spyder. But that version didn’t make it to production. The 918 Spyder was the second plug-in hybrid car manufactured by Porsche, after the 2014 Panamera S E-Hybrid. The 918 Spyder is powered by a 4,593 cc naturally aspirated V8 engine built on the same architecture as the one used in the RS Spyder Le Mans Prototype racing car without any engine belts. The engine weighs 135 kg (298 lb) according to Porsche and delivers 599 bhp at 8,700 rpm and 540 Nm (398 lb/ft) of maximum torque at 6,700 rpm. This is supplemented by two electric motors delivering an additional 282 bhp. One 154 bhp electric motor drives the rear wheels in parallel with the engine and also serves as the main generator. This motor and engine deliver power to the rear axle via a 7-speed gearbox coupled to Porsche’s own PDK double-clutch system. The front 127 bhp electric motor directly drives the front axle; an electric clutch decouples the motor when not in use. The total system delivers 874 bhp and 1,280 Nm (944 lb/ft) of torque. Porsche provided official performance figures of 0-100 km/h (62 mph) in 2.6 seconds, 0-200 km/h (120 mph) in 7.2 seconds, 0-300 km/h (190 mph) in 19.9 seconds and a top speed of 345 km/h (214 mph). Those numbers were surpassed in independent tests which yielded 2.5 seconds for 0-100 km/h, 7.0 seconds for 0-200 km/h, 19.1 seconds for 0-300 km/h, a top speed of 351.5 km/h (218.4 mph) and 17.75 seconds for the standing kilometer with a speed of 295.9 km/h (183.9 mph). The energy storage system is a 312-cell, liquid-cooled 6.8 kWh lithium-ion battery positioned behind the passenger cell. In addition to a plug-in charge port at the passenger-side B pillar, the batteries are also charged by regenerative braking and by excess output from the engine when the car is coasting. CO2 emissions are 79 g/km and fuel consumption is 3 L/100 km (94 mpg) under the New European Driving Cycle (NEDC). The U.S. Environmental Protection Agency (EPA) under its five-cycle tests rated the 2015 model year Porsche 918 Spyder energy consumption in all-electric mode at 50 kWh per 100 miles, which translates into a combined city/highway fuel economy of 3.5 L/100 km (81 mpg). When powered only by the gasoline engine, EPA’s official combined city/highway fuel economy is 26 mpg. The 918 Spyder’s engine is based on the unit used in the Porsche RS Spyder. The 4.6 litre V8 petrol engine can recharge an empty battery on about two litres of fuel. The supplied Porsche Universal Charger requires seven hours to charge the battery on a typical 110 volt household AC socket or two hours on a dedicated Charging Dock installed with a 240 volt industrial supply. An optional DC Speed Charging Station can restore the battery to full capacity in 25 minutes. The 918 Spyder offers five different running modes: E-Drive allows the car to run under battery power alone, using the rear electric motor and front motor, giving a range of 29 kilometres (18 mi) for the concept model. The official U.S. EPA all-electric range is 12 mi (19 km). The total range with a full tank of gasoline and a fully charged battery is 420 miles (680 km) according to EPA tests. Under the E-Drive mode the car can attain a maximum speed of 150 km/h (93 mph). Two hybrid modes (Hybrid, and Race) use both the engine and electric motors to provide the desired levels of economy and performance. In Race mode a push-to-pass button initiates the Hot Lap setting, which delivers additional electrical power. The chassis is a carbon-fibre-reinforced plastic monocoque and the brakes used are electromechanical brakes. The production version was unveiled at the 2013 Frankfurt Motor Show. The 918 Spyder was produced in a limited series and it was developed in Weissach and assembled in Zuffenhausen. Pricing for the 918 Spyder started at €611,000 (US$845,000) or £511,000. Production ended in June 2015 as scheduled. The country with the most orders was the United States with 297 units, followed by China and Germany with approximately 100 orders each, and Canada ordering 35 units.

ROLLS ROYCE

The Rolls-Royce Silver Ghost name refers both to a car model and one specific car from that series. Originally named the “40/50 h.p.”  the chassis was first made at Royce’s Manchester works, with production moving to Derby in July 1908, and also, between 1921 and 1926, in Springfield, Massachusetts, USA. Chassis no. 60551, registered AX 201, was the car that was originally given the name “Silver Ghost”. Other 40/50 hp cars were also given names, but the Silver Ghost title was taken up by the press, and soon all 40/50s were called by the name, a fact not officially recognised by Rolls-Royce until 1925, when the Phantom range was launched. The Silver Ghost was the origin of Rolls-Royce’s claim of making the “best car in the world” – a phrase coined not by themselves, but by the prestigious publication Autocar in 1907. The chassis and engine were also used as the basis of a range of Rolls-Royce Armoured Cars. In December 1923, four friends of Woodrow Wilson chipped in to buy the former president a Silver Ghost, just weeks before Wilson’s death in February 1924. The car was modified so that Wilson, who was disabled, could enter and exit the car more easily. In 1906, Rolls-Royce produced four chassis to be shown at the Olympia car show, two existing models, a four-cylinder 20 hp and a six-cylinder 30 hp, and two examples of a new car designated the 40/50 hp. The 40/50 hp was so new that the show cars were not fully finished, and examples were not provided to the press for testing until March 1907. The car at first had a new side-valve, six-cylinder, 7036 cc engine (7428 cc from 1910) with the cylinders cast in two units of three cylinders each as opposed to the triple two-cylinder units on the earlier six. A three-speed transmission was fitted at first with four-speed units used from 1913. The seven-bearing crankshaft had full pressure lubrication, and the centre main bearing was made especially large to remove vibration, essentially splitting the engine into two three-cylinder units. Two spark plugs were fitted to each cylinder with, from 1921, a choice of magneto or coil ignition. The earliest cars had used a trembler coil to produce the spark with a magneto as an optional extra which soon became standard – the instruction was to start the engine on the trembler/battery and then switch to magneto. Continuous development allowed power output to be increased from 48 bhp at 1,250 rpm to 80 bhp at 2,250 rpm. Electric lighting became an option in 1914 and was standardised in 1919. Electric starting was fitted from 1919 along with electric lights to replace the older ones that used acetylene or oil. Development of the Silver Ghost was suspended during World War I, although the chassis and engine were supplied for use in Rolls-Royce Armoured Cars. A blue 1909 Silver Ghost known as Blue Mist, previously owned by an Irish lord, was used by Lawrence of Arabia as his personal staff car during the Arab Revolt. Construction of a replica Blue Mist began in 2018. The chassis had rigid front and rear axles and leaf springs all round. Early cars only had brakes on the rear wheels operated by a hand lever, with a pedal-operated transmission brake acting on the propeller shaft. The footbrake system moved to drums on the rear axle in 1913. Four-wheel servo-assisted brakes became optional in 1923. Despite these improvements the performance of the Silver Ghost’s competitors had improved to the extent that its previous superiority had been eroded by the early 1920s. Sales declined from 742 in 1913 to 430 in 1922. The company decided to launch its replacement which was introduced in 1925 as the New Phantom. After this, older 40/50 models were called Silver Ghosts to avoid confusion. A total of 7874 Silver Ghost cars were produced from 1907 to 1926, including 1701 from the American Springfield factory. The documented chassis price listed for the 1921 American version was US$11,750. Many of them still run today.

The Rolls-Royce Phantom was Rolls-Royce’s replacement for the original Silver Ghost. Introduced as the New Phantom in 1925, the Phantom had a larger engine than the Silver Ghost and used pushrod-operated overhead valves instead of the Silver Ghost’s side valves. The Phantom was built in Derby, England, and Springfield, Massachusetts, in the United States. There were several differences in specification between the English and American Phantoms. The Phantom was replaced by the Phantom II in 1929. The designation Phantom I was never used by Rolls-Royce; it is a construct of enthusiasts applied to help distinguish it from other generations with the same model name. Introduced in 1925, the New Phantom was Rolls-Royce’s second 40/50 hp model. To differentiate between the 40/50 hp models, Rolls-Royce named the new model “New Phantom” and renamed the old model “Silver Ghost”, which was the name given to their demonstration example, Registration No. AX201. The name Phantom was a nod to the previous “Silver Ghost”, remarking on the vehicles “extraordinary stealth”[3] and quietness in comparison to other vehicles offered at the time. When the New Phantom was replaced by another 40/50 hp model in 1929, the replacement was named Phantom II and the New Phantom was commonly referred to as Phantom I to this day. While Rolls-Royce themselves did not use the term “Phantom I” until their recent acquisition by BMW Group, New Phantoms were referred to as such in period and are commonly called Phantom I by enthusiasts, concours events, and owner’s clubs. One major improvement over the Silver Ghost was the new pushrod-OHV straight-6 engine. Constructed as two groups of three cylinders with a single detachable head, the engine was described by Rolls-Royce as producing “sufficient” power. The engine used a 4+1⁄4 in (108.0 mm) bore and undersquare 5+1⁄2 in (139.7 mm) stroke for a total of 7.7 L (7,668 cc) of displacement. In 1928, the cylinder heads were upgraded from cast iron to aluminium; this caused corrosion problems. The separate gearbox connected through a rubberised fabric flexible coupling to the clutch and through a torque tube enclosed drive to the differential at rear, as in the Silver Ghost. The New Phantom used the same frame as the Silver Ghost, with semi-elliptical springs suspending the front axle and cantilever springs suspending the rear axle. Four-wheel brakes with a servo-assistance system licensed from Hispano-Suiza were also specified, though some early US models lacked front brakes. Like the Silver Ghost, the New Phantom was constructed both at Rolls-Royce’s Derby factory in the United Kingdom and at a factory in Springfield, Massachusetts in the United States. The US factory produced New Phantoms from 1926 to 1931. Principal differences between the US and UK models included wheelbases and transmissions. Both versions were specified with the same standard 143+1⁄2 in (3,645 mm) wheelbase; the long-wheelbase U.S. model was 146+1⁄2 in (3,721 mm) and the UK 150+1⁄2 in (3,823 mm). Both versions used a single dry-plate clutch, with US models equipped with a centre change 3-speed transmission and UK a 4-speed. Other minor differences include fuel gauge placement, with the UK New Phantom’s at the tank but some US models having one on the dash, and manual central lubrication systems. The UK Phantom employed Enots nipples, some times as many as 50, which required attachment of a special Enots oil pressure gun and needed time-consuming service at 500, 1000 and 2000 mile intervals; the US model used a centralized Bijur system which lubricated all the oiling points with a stroke of a single pump. Only the chassis and mechanical parts were produced by Rolls-Royce. The body was made and fitted by a coachbuilder selected by the owner. British coachbuilders who produced bodies for New Phantoms included Barker, Park Ward, [Windovers], Thrupp & Maberly, Mulliner, Hooper. Continental houses such as Saoutchik, Henry Binder and Kellner in Paris, Erdmann and Rossi in Berlin, Baltasar Fiol in Spain, Nordberg in Sweden and the Italian coachbuilder Zagato also produced coachwork for the New Phantom, just to name a few. Despite the availability of a US-built chassis, a handful of British-made Phantoms were outfitted with American coachwork. 2269 were made in the UK and a further 1650 in the US.

The Rolls-Royce 20/25 is the second of Rolls-Royce Limited’s inter-war entry-level models. Built between 1929 and 1936, it was very popular, becoming the most successful selling inter-war Rolls-Royce. Its success enabled Rolls-Royce to survive the Great Depression, and remain one of World’s great brands. 3,827 20/25s were produced, and more than 70% of these survive in use. The 20/25 replaced the highly successful 20 hp Rolls-Royce Twenty that had been introduced in 1922. The target market for the 20/25 was the same as the Twenty – the luxury, owner driver market. The project to develop the next generation 20 hp was code named Goshawk. The goal for the new model was to increase power & performance. This was achieved by increasing the bore from 3 to 3.25 inches. The stroke was unchanged at 4.5 inches. This increased capacity by 17%, from 3,128 to 3,675cc, and raised the RAC rating up to 25.4 hp. The new 20/25 model was debuted at the 1929 Olympia Motor Show. It proved very popular, and became Rolls-Royce’s greatest inter-war success. 3,827 were 20/25 hp made – more than twice as many as its larger sibling the Phantom II. The 20/25’s popularity saved Rolls-Royce in the 1930s. In 1936 the 20/25 model was replaced by the 25/30, in which the bore was further increased to 3.5 inches. In 1938 the 25/30 was given a new chassis with independent front suspension, and became the Wraith. The 20/25 also enabled Rolls-Royce to quickly capitalize on its 1931 acquisition of Bentley Motors Ltd. As part of integrating its acquisition, Rolls-Royce management discontinued the Bentley 8 Litre car due to the perceived market overlap with the Phantom II. This meant the acquisition brought with it the Bentley brand; debt; engineers; and manufacturing employees, but no car to produce. They quickly decided to create a new Bentley using the 20/25 engine with some adaptations, and a chassis that had been developed for a 2¾ litre Rolls-Royce that had been intended as an economy version of the 20/25 but had been cancelled. This formed the basis of the first “Derby Bentley” – the Bentley 3½ litre. The model was very successful; became known as the “Silent Sports Car”; and was another major contribution of the 20/25 to the success of Rolls-Royce.

The Rolls-Royce Phantom II was the third and last of Rolls-Royce’s 40/50 hp models, replacing the New Phantom in 1929. It used an improved version of the New Phantom engine in an all-new chassis. A “Continental” version, with a short wheelbase and stiffer springs, was offered. The Phantom II used a refinement of the New Phantom’s 7,668 cc pushrod-OHV straight-6 engine with a new crossflow cylinder head. Unlike on previous 40/50 hp models, the engine was bolted directly to the 4-speed manual transmission. Synchromesh was added on gears 3 and 4 in 1932 and on gear 2 in 1935. Power was transmitted to the rear wheels using an open driveshaft, a hypoid bevel final drive, and Hotchkiss drive, replacing the torque tube from a remotely mounted gearbox used on earlier 40/50 hp models. The chassis of the Phantom II was completely new. The front axle was mounted on semi-elliptical leaf springs as on earlier 40/50 hp models, but the rear axle was now also mounted on semi-elliptical springs instead of cantilever springs. This, along with the drivetrain changes, allowed the frame to be lower than before, improving the handling.  The 4-wheel servo-assisted brakes from the Phantom I were continued, and the Bijur centralized lubrication system from the Springfield-built Phantom I was included on all Phantom II chassis.  Only the chassis and mechanical parts were made by Rolls-Royce. The body was made and fitted by a coachbuilder selected by the owner. Some of the most famous coachbuilders who produced bodies for Rolls-Royce cars are Park Ward, Brewster, Thrupp & Maberly, Mulliner, Carlton, Windovers, and Hooper. Outside the UK, cars were bodied in Australia by Martin & King, Italy by Castagna, Spain by Baltasar Fiol, Germany by Erdmann und Rossi, Sweden by Nordberg, Belgium by Van den Plas (Bruxelles,) The Netherlands by Van Rijswijk, France by Saoutchik, Kellner, Binder and Gaston Grümmer, and the United States by Brewster and F.R. Wood. The standard wheelbase of the Phantom II was 150 inches (3,800 mm). A 144 inches (3,700 mm) short-wheelbase chassis was also available. A total of 1,681 Phantom II chassis of all types were built. Henry Royce had body designer Ivan Evernden design him a one-off short-wheelbase Phantom II. Designated 26EX, the car had a tuned engine, five-leaf springs that were stiffer than standard and a Barker four-seat lightweight close-coupled saloon body painted with an artificial pearl lacquer made from ground herring scales. The sales department initially showed no interest in 26EX but, when Evernden returned to the office from the 1930 Biarritz Grand Concours d’Elegance, where 26EX had won the Grand Prix d’Honneur, he found that the sales department had already announced the new “Phantom II Continental Saloon”, prepared a brochure for it, and costed it. According to Evernden, neither he, Royce, nor the Rolls-Royce sales department had written specifications for the “Continental” model, although he and Royce had a clear specification in mind. Based on Evernden’s writings and examination of company records, historian Ray Gentile determined that the common specifications of the Continental chassis were the short wheelbase and stiffer, five-leaf springs. By this definition, two hundred and eighty-one Continental Phantom II’s were produced, including 125 left-hand drive versions.

The Rolls-Royce 25/30 built between 1936 and 1938 is an updated version of the 20/25 with larger engine to provide more power, as over-large bodies had often been fitted to the earlier model leading to complaints about its performance. The in-line 6-cylinder, overhead-valve 25/30 hp engine is similar to that used in the 20/25 but increased in capacity to 4,257 cc (259.8 cu in) by increasing the bore from 3.25 inches (8.3 cm) to 3.5 inches (8.9 cm), with the stroke remaining at 4.5 inches (114.3 mm). The compression ratio is 6:1. A single proprietary Stromberg downdraught carburettor replaced the Rolls-Royce one, and magneto ignition was no longer fitted, but a standby coil was provided. The four-speed gearbox is mounted in unit with the engine, and a traditional right-hand change used. Synchromesh is fitted to third and top gears. The riveted chassis has rigid front and rear axles suspended by half-elliptic springs with hydraulic dampers. Braking is on all four wheels assisted by a mechanical servo, famously under licence of Hispano-Suiza. Separate rear brakes are fitted for the handbrake. The traditional Rolls-Royce radiator with triangular top was used with vertical louvres, the opening angle of which is controlled thermostatically to control engine cooling. Only the rolling chassis and mechanical parts were made by Rolls-Royce. The body was made and fitted by a coachbuilder selected by the owner. Some of the most famous coachbuilders who produced bodies for Rolls-Royce cars are Park Ward, Thrupp & Maberly, H. J. Mulliner & Co., Arthur Mulliner and Hooper.

The Silver Wraith was the first post-war Rolls-Royce. It was made from 1946 to 1958 as only a chassis at the company’s Crewe factory, its former Merlin engine plant, alongside the shorter Bentley Mark VI. The Bentley was also available as a chassis for coachbuilders, but for the first time could be bought with a Rolls-Royce built Standard Steel body. The use of the name “wraith” coincided with the established tradition of naming models after “ghosts”. It was announced by Rolls-Royce in April 1946 as the 25/30 hp replacement for the 1939 Wraith in what had been their 20 hp and 20/25 hp market sector, that is to say Rolls-Royce’s smaller car. The size was chosen to be in keeping with the mood of post-war austerity. Even very limited production of the chassis of the larger car, the Phantom IV, was not resumed until 1950 and then, officially, only for Heads of State. Improvements announced were: chromium-plated cylinder bores for the engine; a new more rigid chassis frame to go with new independent front suspension; and a new synchromesh gearbox. Chassis lubrication was now centralised. The straight six-cylinder postwar engine, which had been briefly made for the aborted by war Bentley Mark V, replaced conventional overhead valve gear with an F-head configuration of overhead inlet valves and side exhaust valves and reshaped combustion chambers. There were new main and big-end bearings and a more efficient drive to the timing gear. To this prewar mix Rolls-Royce added chromed bores. Initially, this engine retained the Mark V’s capacity of 4,257 cc increased from 1951 to 4,566 cc and in 1955, after the introduction of the (standard wheelbase) Silver Cloud, to 4,887 cc for the remaining Silver Wraiths. The first cars had an entirely new 127 inch (3226 mm) wheelbase chassis which differed considerably from that of the pre-war Wraith and was much nearer rigid. It matched the new Bentley chassis but with an extra 7 inch section added to the centre. The new chassis had coil sprung independent front suspension, which required a very rigid chassis to function properly, and at the rear conventional semi-elliptic springs and live axle. The braking system was a hydro-mechanical hybrid of hydraulic fronts and mechanical rears using the mechanical servo similar to that of the pre-war cars. The last short-wheelbase cars were delivered in November 1953. The long, 133 inch (3378 mm), wheelbase chassis was announced in 1951 and the first delivered in January 1952. 639 were made by the time of the last deliveries in October 1958. This was not quite the last Rolls-Royce model to be supplied as a rolling chassis ready for a wide variety of bespoke coachwork designed and made by a rapidly declining number of specialist coachbuilders. Most of the bodies selected used “formal” limousine designs. From 1949 until 1955 customers wishing to buy a Rolls-Royce fitted with a much smaller standard steel body could purchase the Silver Dawn. It rode on a chassis seven inches shorter than the Silver Wraith, and was almost identical to Rolls-Royce’s Bentley Standard Steel saloon available alongside the Silver Wraith since July 1946.

 

The Rolls-Royce Silver Dawn is a full-size luxury car that was produced by Rolls-Royce at their Crewe works between 1949 and 1955. It was the first Rolls-Royce car to be offered with a factory built body which it shared, along with its chassis, with the Bentley Mark VI until 1952 and then the Bentley R Type until production finished in 1955. The car was first introduced as an export only model. The left hand drive manual transmission models had a column gear change, while right hand drives had a floor change by the door. In the British home market the Silver Dawn only became available from October 1953, with the introduction of the model corresponding to the Bentley R Type. In 1944 W. A. Robotham saw that there would be limited postwar demand for Rolls-Royce or Bentley chassis to be fitted with bodies from specialist coachbuilders, and negotiated a contract with the Pressed Steel Company for a general-purpose body to carry four people in comfort on their postwar rolling chassis, fitted as always with a distinct Rolls-Royce or Bentley radiator. Though he stretched the demand to 2000 per year, Pressed Steel were “nonplussed” by the small demand. A mere 760 were produced between 1949 and 1955. Silver Dawn Series A-D had bodywork identical to the Mark VI. In 1953, with the “E” series (Chassis Number SKE2), the Silver Dawn body was modified in parallel to the Bentley Mk VI body and a large boot was added. While the Bentley Mk VI was renamed the Bentley R after this change, the Rolls-Royce Silver Dawn kept its name. Even with mass produced Standard Steel bodies, all panels forward of the bulkhead/firewall were slightly different for the Rolls-Royce from those fitted to the Bentley. In 1951 the Silver Dawn was upgraded to the 4 1/2 L engine and the full flow oil filter (Chassis Number LSFC2). In 1953 the high compression cylinder head was fitted from Chassis number SMF66 and from the same chassis number on the Bentley Mk VI type camshaft was fitted to left hand drive vehicles. Earlier models up to circa May 1954 had a different fascia from the Bentley Mk.VI and ‘R’ Type, and were fitted with a single exhaust system. Later models from the SRH2 chassis series had the Bentley style fascia and the twin exhaust system, as fitted to the Bentley ‘R’ Type. The inline six-cylinder engine had overhead inlet and side exhaust valves and had a capacity of 4,257 cc until 1951 when it was enlarged to 4,566 cc. The carburettor up to Chassis number SFC100 was a single double downdraught Stromberg type AAV 26 until 1952 when it was replaced by a Zenith DBVC42. A 4-speed manual gearbox was fitted to all cars at first, with a 4-speed automatic becoming an option in late 1952 on the ‘E’ Series chassis, and on the corresponding Bentley R Type chassis. There are conflicting reports if the automatic gearbox became standard in the Silver Dawn, but both manual and automatic options were available until the end of the production run. However the original invoice for a 1955 UK model (Chassis Number SVJ115) clearly shows that the Automatic Gearbox was an optional extra and cost the buyer £70.0.0. The suspension was independent at the front using coil springs while at the rear the live axle used half elliptic leaf springs. The car had a separate chassis made with traditional riveted construction until 1953 after which it was welded. Servo assisted 12.25 in (311 mm) drum brakes were used, hydraulically operated at the front but retaining mechanical operation at the rear. Although many cars were fitted with factory built bodies, others were supplied to external coachbuilders.

The Rolls-Royce Silver Cloud is a luxury automobile produced from April 1955 to March 1966. It was the core model of the Rolls-Royce range during that period. The Silver Cloud replaced the Silver Dawn and was, in turn, replaced by the Silver Shadow. The John P. Blatchley design was a major change from the pre-war models and the highly derivative Silver Dawn. As part of a range rationalisation, the Bentley S1 was made essentially identical, apart from its radiator grille and badging. Construction is body-on-frame, which permitted special bodied versions, though the overwhelming majority were built with the standard Pressed Steel Company manufactured steel body shell. A light-weight aluminium alloy was used for doors, bonnet/hood and boot/trunk lid. The chassis is a simple steel box section, welded together and very rigid. The car is 5.38 m (212 in) long, 1.90 m (75 in) wide, and weighs 1.95 tonnes. The engine is a 155 hp / 4000 rpm 4.9 L six-cylinder unit with inlet over exhaust valves: twin SU carburettors were added in September 1957. The standard transmission was a four-speed automatic, the General Motors designed Hydramatic transmission. The turning circle was 41 feet 8 inches (12.70 m). Brakes are hydraulic and assisted by the Rolls-Royce mechanical servo with 11 in (279 mm) drums and suspension was independent coils at the front and semi-elliptic springs at the rear. Twin brake master cylinders were incorporated from April 1956. Power steering and air conditioning became available as options in 1956. A long-wheelbase version lengthened by 4 in (102 mm) was also made available in September 1957, outwardly very similar to the existing car but offering improved leg space for rear-seat passengers.  The coachbuilder Harold Radford offered conversions of the 4-door saloon into an estate car. One of these conversions, chassis no. LSMH65, sold in March 2017 for $583,000 (inclusive of applicable buyer’s fee) at RM Sotheby’s Amelia Island auction. The Silver Cloud II was introduced in 1959. It was little changed externally, but was given a new Rolls-Royce developed 6.2 L V8 engine, which pushed the weight to 2.11 tonnes. Performance was greatly improved and top speed was raised to 183 km/h (114 mph), but the main improvements were in acceleration and torque. Power steering became standard. Electrically operated windows were now available as an option. Although the improved performance of the new car was welcomed, commentators of the time noted that the V8-engined Silver Cloud II was neither as quiet nor as smooth as the straight-six-cylinder-engined Silver Cloud I, despite the new engine’s hydraulic tappet operation. The new wet-linered V8 was also a little cramped in an engine bay intended originally for a narrower unit: in order to change the spark plugs it was necessary to remove the front wheel on the car’s right side. There seems to have been a problem with crankshaft breakages in the earlier V8s: this was blamed on lack of lubrication to the bearings. The basic architecture of the Silver Cloud II did not change between 1959 and 1963, but there were numerous minor changes implemented, notable among them a succession of improvements to the ventilation system. Interior changes in 1961 included the adoption of blue instrument lighting, the introduction of a combined indicator / headlamp flasher switch and of a handbrake warning light. A remodelled rear light assembly was introduced in May 1962 and a change to single sealed-beam headlamps was made in August 1962. The Silver Cloud III was first displayed to the public at the Paris salon at the beginning of October 1962 but along with the Bentley S3 the cars were displayed on a specialist coachwork stand as if the modifications were to the special order of a particular customer. External dimensions were slightly altered, the interior remodelled, the weight reduced by a little over 100 kg (220 lb) and improvements made to the engine which included fitting 2-inch (51 mm) SU carburettors in place of the 1+3⁄4 inch units used on the Series II Silver Cloud. The compression ratio was increased to 9:1, reflecting the higher octane levels of premium fuel in major markets, although the option of a lower 8:1 compression ratio was still offered in markets where non-availability of higher octane fuels might be an issue. Rolls-Royce, as before, refused to disclose overall engine power output, but indicated that there had been an improvement of “perhaps 7%”. Increased power and weight reduction boosted speed and performance slightly. The engine now included a nitride hardened crankshaft to reflect the extra power being generated and in response to reports of broken crankshafts in the earlier V8 Silver Clouds. The transmission was a GM Hydramatic which Rolls-Royce used under licence. The headlights were grouped in a four-headlamp layout subsequently continued in the later Silver Shadow. Other external changes included a slightly increased slope of the bonnet to correspond with a 1+1⁄2 inches (3.8 cm) reduction in radiator grille height. Between 1963 and 1966 there were no major changes. Stainless steel wheel trims replaced chrome-plated ones in April 1963, and an improved rear window demister was introduced in November of the same year. Wider front seats were fitted in January 1964, and five months later a revised headlamp surround now incorporated a very small RR monogram. A chrome badge reading “Silver Cloud III” in an italic font can be seen on the right bottom side of the boot of most UK and European delivered examples, whilst US versions were delivered without this badge. As with earlier models, Rolls-Royce continued to make the Silver Cloud chassis available to traditional coachbuilders. A notable version is the Fixed Head and Drop Head Coupe styled by Mulliner Park Ward, having unusual slanted headlights, also found on contemporary Italian designed or Italian-influenced high performance cars from Lancia, Triumph, Lagonda and Gordon-Keeble. It was derived from the earlier Park Ward design for the Bentley S1 and S2 Continentals, made also available for the S3. Some 100 of the 328 coach-built Silver Cloud IIIs were of this style.

When new, the Silver Shadow was considered a big car, but looking at this one, it does not seem quite so massive any more. The Silver Shadow was produced from 1965 to 1976, and the Silver Shadow II from 1977 to 1980. Initially, the model was planned to be called “Silver Mist”, a natural progression from its predecessor Silver Cloud. The name was changed to “Silver Shadow” after realising that “Mist” is the German word for manure, rubbish, or dirt. The design was a major departure from its predecessor, the Silver Cloud; although several styling cues from the Silver Cloud were modified and preserved, as the automobile had sold well. The John Polwhele Blatchley design was the firm’s first single bow model. The original Shadow was 3 1⁄2 inches narrower and 7 inches shorter than the car it replaced, but nevertheless managed to offer increased passenger and luggage space thanks to more efficient packaging made possible by unitary construction. Aside from a more modern appearance and construction, the Silver Shadow introduced many new features such as disc rather than drum brakes, and independent rear suspension, rather than the outdated live axle design of previous cars. The Shadow featured a 172 hp 6.2 litre V8 from 1965 to 1969, and a 189 hp 6.75 litre V8 from 1970 to 1980. Both powerplants were coupled to a General Motors-sourced Turbo Hydramatic 400 automatic gearbox, except on pre-1970 right-hand-drive models, which used the same 4-speed automatic gearbox as the Silver Cloud (also sourced from General Motors, the Hydramatic). The car’s most innovative feature was a high-pressure hydropneumatic suspension system licensed from Citroën, with dual-circuit braking and hydraulic self-levelling suspension. At first, both the front and rear of the car were controlled by the levelling system; the front levelling was deleted in 1969 as it had been determined that the rear levelling did almost all the work. Rolls-Royce achieved a high degree of ride quality with this arrangement. In 1977, the model was renamed the Silver Shadow II in recognition of several major changes, most notably rack and pinion steering; modifications to the front suspension improved handling markedly. Externally, the bumpers were changed from chrome to alloy and rubber starting with the late 1976 Silver Shadows. These new energy absorbing bumpers had been used in the United States since 1974, as a response to tightening safety standards there. Nonetheless, the bumpers on cars sold outside of North America were still solidly mounted and protruded 2 in less. Also now made standard across the board was the deletion of the small grilles mounted beneath the headlamps. Outside of North America, where tall kerbs and the like demanded more ground clearance, a front skirt was also fitted to the Silver Shadow II and its sister cars. In 1979 75 Silver Shadow II cars were specially fitted to commemorate the 75th anniversary of the company with the original red “RR” badges front and rear, pewter/silver paint, grey leather with red piping, scarlet red carpets, and a silver commemorative placard on the inside of the glove box door. 33 75th anniversary cars were designated for and shipped to the North American market. 8425 examples of the Shadow II were made, which, when added to the total of over 16,000 of the first generation cars made this the biggest selling Rolls Royce of all time.

The Corniche was a development of the Rolls-Royce Silver Shadow, with the two door variants of that model marketed as the “Silver Shadow Mulliner Park Ward two door fixed head coupé & drop head coupé” until March 1971 when the Corniche name was applied. The exterior design was by John Polwhele Blatchley. The model was assembled and finished in London at Mulliner Park Ward as continuation of the 1965 Silver Shadow coupe and 1966 drophead. A Bentley version was also sold, becoming known as the Continental in 1984. The Corniche, available as coupé or convertible, used the standard Rolls-Royce 6750 cc V8 engine with an aluminium-silicon alloy block and aluminium cylinder heads with cast iron wet cylinder liners. Twin SU carburettors were initially fitted, but were replaced with a single Solex 4A1 four-barrel carburettor introduced in 1977. A three-speed automatic transmission (a Turbo Hydramatic 350 sourced from General Motors) was standard. A four-wheel independent suspension with coil springs was augmented with a hydraulic self-levelling system (using the same system as did Citroën, but without pneumatic springs, and with the hydraulic components built under licence by Rolls-Royce), at first on all four, but later on the rear wheels only. Four wheel disc brakes were specified, with ventilated discs added for 1972. The car originally used a 119.75 in (3,042 mm) wheelbase. This was extended to 120 in (3,048 mm) in 1974 and 120.5 in (3,061 mm) in 1979. The Corniche received a mild restyling in the spring of 1977. Difference included rack-and-pinion steering, alloy and rubber bumpers, aluminium radiator, oil cooler and a bi-level air conditioning system was added. Later changes included a modified rear independent suspension in March 1979. In March 1981, after the Silver Spirit had gone on sale, the Coupé version of the Corniche and its Bentley sister were discontinued. For 1985 there were also cosmetic and interior changes. Corniche models received Bosch KE/K-Jetronic fuel injection in 1977. This engine, called the L410I, produced approximately 240 PS at just above 4,000 rpm for a top speed of 190 km/h (118 mph). The Bentley version was updated in July 1984 with a new name, the Continental, revised and colour-coded bumpers, rear view mirrors, a new dash and improvements to the seats. Production totalled 1090 Rolls-Royce Corniche Saloons, 3239 Rolls-Royce Corniche Convertibles, 69 Bentley Corniche Saloons and 77 Bentley Corniche Convertibles.

At launch, the Camargue was the Rolls-Royce’s flagship and the most expensive production car in the world (but a bit cheaper than the Phantom).  At its 1975 press debut, Rolls-Royce highlighted automatic split-level climate control system, the first of its kind. According to Rolls Royce, the system’s development took eight years. The recommended price of a new Camargue at launch on the UK market in March 1975 was £29,250, including sales taxes. Rapid currency depreciation would greatly raise the price of the Camargue in the late 1970s, both in the UK and North America. The Camargue shared its platform with the Rolls-Royce Corniche and Silver Shadow. It was powered by the same 6.75 litre V8 engine as the Silver Shadow, although the Camargue was slightly more powerful. The transmission was also carried over — a General Motors Turbo-Hydramatic 3-speed automatic. The first 65 Camargues produced used SU carburettors, while the remaining 471 used Solex units. The Camargue was fitted with the Silver Shadow II’s power rack and pinion steering rack in February 1977. In 1979, it received the rear independent suspension of the Silver Spirit. With a 3048 mm (120 in) wheelbase, the Camargue was the first Rolls-Royce automobile to be designed to metric dimensions,and was the first Rolls-Royce to feature an inclined rather than perfectly vertical grille; the Camargue’s grille was slanted at an inclined angle of seven degrees. The Camargue received a varied reception, having ranked as one of the “10 Worst Cars”‘as chosen in 2010 by readers of The Globe and Mail; having ranked 38 in the 2005 book Crap Cars by Richard Porter (the author saying the car “looked utterly terrible)” and having ranked 92 in a 2008 poll of the 100 ugliest cars of all time by readers of The Daily Telegraph. Autoblog said the Camargue had been ranked “conspicuously low on the list,” adding the Camargue “really was horrid, no matter how well it sold.” And it sold just 531 cars during its production life.

Follow on to the Silver Shadow was the Rolls-Royce Silver Spirit, produced from 1980 to 1997. It was the first model in the SZ series. The Silver Spur is a long-wheelbase version of the Silver Spirit, produced from 1980 to 2000. It was the first car to feature a retractable Spirit of Ecstasy. The spring-loaded mascot sank into the radiator shell if dislodged from its position. The Silver Spirit was introduced by Rolls-Royce in 1980 as the first of a new generation of company models. It formed the basis for the Flying Spur, Silver Dawn, Touring Limousine, Park Ward, and Bentley Mulsanne/Eight series. The Spirit/Spur carried over the basic design of the Silver Shadow, its 6.75 L L410 V8 engine and GM-sourced THM400 3-speed automatic gearbox, and similarly styled unitary bodywork manufactured at Pressed Steel. The Spur/Spirit continued the Silver Shadow’s emphasis on ride quality by utilising its hydropneumatic self-levelling suspension, modified with Girling automatic hydraulic ride height control system and gas-charged shock absorbers. The Silver Spirit II and Silver Spur II were refinements of the original models, introduced at the 1989 Frankfurt Motor Show. Suspension design saw the most change, with “Automatic Ride Control” introduced, a fully automatic system that adjusted dampers at all four wheels in real time. Other updates included the adoption of ABS and fuel injection as standard for all models and markets. The last Mark I Silver Spirit/Spur was chassis no KCH27798, with Mark II cars starting with 29001. The fuel injection system was now Bosch’s MK-Motronic. Originally retaining the three-speed Turbo Hydramatic GM400 transmission from earlier Spirits/Spurs, a four-speed unit (the GM 4L80E) was introduced in the winter of 1991. The size of the petrol tank was also increased, up to 107 L (24 imp gal), meaning that the car’s range was now up to well over 500 km (311 mi). Exterior and interior changes were minimal, with a considerably smaller steering wheel and two additional ventilation outlets added to the fascia mildly modernising the look up front. The Silver Spirit III and Silver Spur III were introduced in 1993, featuring engine improvements and some cosmetic updates. A new design of intake manifold and cylinder heads increased power output. The parameters of the semi-active suspension system were modified so that shock absorbers would default into “soft” ride mode when they wore out (rather than “hard” in the previous Mark II, noticeably impacting ride quality). Dual airbags were introduced inside, along with independent adjustment of the rear seats. The 1994–1995 Flying Spur was a turbocharged, higher performance version of the Silver Spur III. 134 cars were produced. The Silver Dawn is a special edition of the Silver Spur III with several additional options, such as Electronic Traction Assistance System and rear seat heaters. The radiator height is reduced by 51 mm (2 in) and the size of the Spirit of Ecstasy was reduced by 20 percent. The new front was later inherited by the Mark IV series. Silver Dawn appeared one year earlier on the American market.  Designed in the autumn of 1992, the New Silver Spirit/New Silver Spur was the final revision of the Silver Spirit and Silver Spur, introduced late in 1995 as a 1996-year model. A marketing decision had been made that the cars should not get a “series IV” designation because the number four is a homonym for death in some Far Eastern languages. Major changes included the introduction of a Garrett turbocharger on all models and the replacement of the previous Bosch engine management systems with one by Zytec. Also new were updated integrated front and rear bumpers and sixteen-inch wheels. As of 1997, the long wheelbase became standard, with limousine models offered in extra-long only. Inside, a wooden column running down the centre of the dashboard was added. Silver Spirit production closed with the model year 1997, although vehicles continued to be produced through 2000 to use up Silver Spirit bodies and parts remaining in stock.

There were plenty of recent Rolls Royce models here, ranging from the Phantom VII, Dawn and Wraith all of which are out of production to the bulky Cullinan and the all-electric Spectre.

TVR

The Cerbera was first shown as a prototype at the 1994 Birmingham Show, entering production in 1996. The name derives from Cerberus the three-headed beast of Greek legend that guarded the entrance of Hades. This was the third car manufactured by TVR under the leadership of Peter Wheeler, and it represented three firsts for the Wheeler-led company: the first hard-top—the Griffith and the Chimaera were both convertibles; the first 2+2—TVRs were traditionally two-seaters; the first to be driven by TVR’s own engines—historically, TVR had purchased engines from mainstream manufacturers like Rover, Ford and Triumph. Prior to the Cerbera, TVR had purchased V8 engines from Rover and then tuned them for their own use. When Rover was purchased by BMW, Peter Wheeler did not want to risk problems should the Germans decide to stop manufacturing the engine. In response, he engaged the services of race engineer Al Melling to design a V8 engine that TVR could manufacture in-house and even potentially offer for sale to other car-makers. In an interview for the television programme Top Gear, Wheeler explained “Basically, we designed the engine as a race engine. It was my idea at the time that if we wanted to expand, we ought to make something that we could sell to other people. We’ve ended up with a 75-degree V8 with a flat-plane crank. The bottom-half of the engine to the heads is exactly as you would see in current Formula One engines.” Wheeler was quoted at the time of the car’s launch as saying that the combination of light weight and high power was too much for a road car, a quote which ensured much free publicity in the press. Enthusiasts still argue about whether this was a typical example of Wheeler’s legendary frankness, or an equally typical example of his PR chief Ben Samuelson’s knack for saving on advertising costs by creating a story. The result was dubbed the “Speed Eight” (official designation ‘AJP8’) after Al Melling, John Ravenscroft and Peter Wheeler, a 4.2 litre V8 producing 360 hp and gave the Cerbera a top speed of 185 mph (297 km/h). A 4.5 litre version of the engine was later offered with 420 hp. The AJP8 has one of the highest specific outputs of any naturally aspirated V8 in the automotive world at 83.3 hp/litre for the 4.2 and 93.3 hp/litre for the 4.5. Later models of the 4.5 litre engine had the ‘Red Rose’ option, which increased output to 440 bhp (97.7 hp/litre) when fuelled with super-unleaded (high octane) and the driver pushed the unmarked button on the dashboard which altered the engine mapping to suit. In some cases, real-world outputs for production V8s (4.5 in particular) were down from TVRs quoted output. Some of these have seen some form of modification (ECU, induction, exhaust etc.) to bring the power back up to the factory quoted output. One of the attractions of the V8 Cerberas for many owners was the loud backfire produced on overrun, particularly at low speeds. In fact this was the result of an argument at the factory between one of TVR’s executives and the engineers mapping the engine. The engineers wanted to map out this “irregularity” to improve fuel efficiency and CO2 emissions, whilst the executive insisted it was exactly the kind of thing owners would like. In the end a compromise was reached in which the popping and banging remained on the 4.5 litre cars. With the success of the Speed Eight program, Wheeler also undertook the design of a “Speed Six” engine to complement it. This engine also made its debut in the Cerbera but was a 4.0 litre inline slant six design with four valves per cylinder to the Speed Eight’s two. In service however it gained a reputation for unreliability and many engines had to be rebuilt. The car itself was designed from the start as a four-seater. The rear seats are smaller than the front, a design commonly referred to as a “2+2”. However, the interior is designed so that the passenger seat can slide farther forward than the driver’s seat. This allows more room for the person sitting behind the front passenger. TVR have referred to this as a “3+1” design. TVR maintained its tradition of building cars that were not only exceptionally powerful but also very light for their size and power output. The Cerbera’s weight was quoted by TVR at 1100 kilograms, although customers claimed the weight varied between 1,060 kg (2,337 lb) and 1,200 kg (2,646 lb). The dashboard was designed especially for the Cerbera and uses a two-spar steering wheel as opposed to the typical three-spar previously found in most TVRs. The reason for this is that minor instruments are located on a small panel below the steering wheel and a third spar in the wheel would have made them difficult to read. Like all TVRs of the Peter Wheeler era, the Cerbera had a long-travel throttle to compensate for the lack of electronic traction-control and very sharp steering. The V8 powered cars were two turns from lock to lock and the Speed Six car was 2.4 turns. This made it easier for experienced drivers to maintain or regain control of the car in the event of a loss of traction but some less experienced drivers complained that it made the cars feel “twitchy” and more responsive than they would otherwise have preferred. In 2000, TVR changed the styling of the car slightly by modifying the headlights to more closely resemble those seen in the TVR Tuscan. The “facelift” features were available with all three engine configurations. In addition, the cars equipped with the 4.5 litre engine were offered with the “lightweight” option, reducing the overall weight through the use of lighter body panels and a slightly reworked interior. The final car was made in 2006.

Taking its name from the Greek name of a lightweight battle-axe used by the Scythians which was feared for its ability to penetrate the armour of their enemies, the final TVR model to be seen here was a Sagaris, a car which made its debut at the MPH03 Auto Show in 2003. The pre-production model was then shown at the 2004 Birmingham Motorshow. In 2005 the production model was released for public sale at TVR dealerships around the world. Based on the TVR T350, the Sagaris was designed with endurance racing in mind. Several design features of the production model lend themselves to TVR’s intentions to use the car for such racing. The multitude of air vents, intake openings and other features on the bodywork allow the car to be driven for extended periods of time on race tracks with no modifications required for cooling and ventilation. The final production model came with several variations from the pre-production show models such as the vents on the wings not being cut out, different wing mirrors, location of the fuel filler and bonnet hinges. As with all modern TVRs the Sagaris ignored the European Union guideline that all new cars should be fitted with ABS and at least front airbags because Peter Wheeler believed that such devices promote overconfidence and risk the life of a driver in the event of a rollover, which TVRs are engineered to resist. It also eschewed electronic driver’s aids (such as traction control or electronic stability control). In 2008, TVR unveiled the Sagaris 2, which was designed to replace the original Sagaris. In the prototype revealed, there were minor changes to the car including a revised rear fascia and exhaust system, and modifications to the interior. Sagaris models. on the rare occasions that they come up for sale, are pricey.

ZENVO