Although I am happy to travel quite significant distances to attend car events, as the reports here evidence, it is always nice to be able to go to something that is local, so there is no need to leave home at the crack of dawn, and which also leaves a significant part of the day free to address those domestic tasks which sometimes have to be fitted in, so attending the local monthly Queen Square Breakfast Club meets is something I relish doing whenever possible.  And it certainly did prove possible in May with the other event for the weekend taking place, slightly unusually, on a Saturday. Outside the dark days of winter, these are held at Eastwood Park, an impressive venue that is actually a few miles north of the city, easily accessible from the A38 and only a few minutes from junction 14 of the M5. Like all such events, no-one really knows exactly how many cars, or what cars will turn up on the day, not even the organiser, as sometimes promised cars fail to be driveable on the day or people’s plans change at the last minute, so whilst there are plenty of inveterate attendees, there are always surprises. The April 2024 event surprised not least because of the huge attendance, perhaps the biggest there has ever been at this venue, so I fell to wondering what treats would be instore as I headed up the M5 for the short journey to Eastwood Park for the May 2024 event. Here is what I saw during the morning:

ABARTH

This time there were three Abarths present, including mine. Rumours started to circulate towards the end of 2014 that Abarth were going to upgrade the Competizione model, so as better to bridge the gap between the Turismo and the 190 bhp 695 Biposto that had been added to the range earlier in the year. It was Geneva 2015 when the result was finally shown to an expectant fan base. Most exciting news was that thanks to a bigger Garrett Turbo, the engine had been tweaked to 180 bhp, and with reduced CO2 emissions. A standard spec that included Koni Dampers, Brembo brakes, Xenon lights, Sabelt seats, Climate Control, parking sensors as well as other refinements that had been added like the TFT instrument display all proved very compelling, so not long after the first cars reached the UK  in June of 2015, I found temptation too hard to resist, and as is well documented here, swapped my 2010 car for one of these. At the time I ordered it, Cordolo Red, a tri-coat pearlescent paint which shimmers in bright sunlight looked set to become one of the most popular colours of the lot, even though it is a cost option. Indeed, the Launch Edition models were all offered either in this colour or Scorpion Black, with black wheels. Surprisingly, the colour was not carried over to the Series 4 cars.

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 cases 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 Punto Evo was launched at the 2010 Geneva Show, with the cars reaching UK buyers in the summer of that year, and it incorporated many of the changes which had been seen a few months earlier on the associated Fiat models, the visual alterations being the most obvious, with the car taking on the nose of the associated Fiat, but adapted to make it distinctively Abarth, new rear lights and new badging. There was more to it than this, though, as under the bonnet, the T-Jet unit was swapped for the 1.4 litre Multi-Air, coupled to a 6 speed gearbox, which meant that the car now had 165 bhp at its disposal. Eventually, Abarth offered an Esseesse kit for these cars, though these are exceedingly rare. Part of the Punto Evo family is the SuperSport, usually identified by the distinctive black bonnet, though not all cars feature it. Just 199 of the SuperSport versions were built, of which around 120 are registered on UK roads. These cars had many of the options from the Punto Evo included as standard. Power came from the 1.4-litre MultiAir turbo engine, tuned to produce 178bhp and 199lb ft of torque, up from 165 of the standard Punto Evo, giving the SuperSport a 0-62 time of 7.5 seconds and a top speed of over 132mph. To help put the power down, the SuperSport was fitted with wider 18″ wheels and optional Koni FSD dampers. Standard equipment included the Blue&Me infotainment system with steering wheel controls, automatic climate control and a popular option was the ‘Abarth Corsa by Sabelt’ sports leather seats. The SuperSport was available in the same colours as the regular Punto Evo, which means white, grey, black and red. This one, belonging to Ben Waite, has been wrapped and is a very distinctive car, which is much admired by all who see it.

AC

Like most of the Cobra models you see these days, this is not one of the original 60s cars but  a much more recreation. Styled to look like the original Cobra 427, this car was made in 1994/5.

ALFA ROMEO

There was just one Alfa Romeo that I spotted here, the modern Giulia in the very distinctive gold colour that became an option a couple of years ago.

ALPINE

One of those enthusiast cars that you rather expect to see at an event like this, the well-respected A110 was here.

ASTON MARTIN

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. A total of 18 different versions of the car were produced during its 12 year life.

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.

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. It remains a current model.

There were a number of other Audi models here, of course, mostly S and RS badged cars. It was this example of the latest RS6 Avant which was captured by my camera.

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.

BMW

The first car to bear the 6 Series nomenclature was the E24, which was launched in 1976, as a replacement for the E9 model 3.0 CS and CSL coupés first produced in 1965. The 3.0 CS was almost changed by adding a few centimeters in height to make it easier for customers to get into the car. However, Bob Lutz rebelled against the decision and rough drafted an alternative version that soon became the 6 series. Production started in March 1976 with two models: the 630 CS and 633 CSi. Originally the bodies were manufactured by Karmann, but production was later taken in-house to BMW. In July 1978 a more powerful variant, the 635 CSi, was introduced that featured as standard a special close-ratio 5-speed gearbox and a single piece black rear spoiler. The bigger bore and shorter stroke facilitated max 218 hp at 5200rpm and a better torque curve. For the first year, the 635 CSi was offered in three colours (Polaris, Henna Red, Graphite), and could also be spotted by the front air dam that did not have attached fog lights. These simple cosmetic changes reportedly worked to reduce uplift on the car at high speeds by almost 15% over the non-spoiler body shape. This early model shared suspension components with the inaugural BMW 5-series, the E12. In 1979 the carburettor 630 CS was replaced with the 628 CSi with its fuel injected 2.8 litre engine taken from the BMW 528i. In 1980 the 635 CSi gained the central locking system that is also controlled from the boot. Also, the E24 body style converted from L-jetronic injection to a Bosch Motronic DME. In 1982 (Europe) and 1983 (US), the E24 changed slightly in appearance, with an improved interior and slightly modified exterior. At the same time, the 635 CSi received a new engine, a slightly smaller-bored and longer-stroked 3430 cc six to replace the former 3453 cc engine and became available with a wide-ratio 5-speed manual or an automatic. This slight change was in fact a major change as pre-1982 cars were based on the E12 5-series chassis; after mid-1982, E24s shared the improved E28 5-series chassis. The only parts that remained the same were some of the exterior body panels. E24s produced after June 1987 came with new, ellipsoid headlamps which projects beam more directly onto road surface (newly introduced E32 7-series also sporting them). The sleeker European bumpers were also discontinued. Previous cars had either a European-standard bumper or a larger, reinforced bumper to meet the US standard requiring bumpers to withstand impact at 5 mph without damage to safety-related components. 1989 was the last year for the E24 with production stopping in April. The E24 was supplanted by the considerably heavier, more complex, and more exclusive 8 Series. BMW Motorsport introduced the M 635 CSi in Europe at the Frankfurt Motor Show in 1983. It is essentially an E24 powered by the powerplant of the BMW M1 – the M88 with 286 PS). Most of the cars were equipped with special metric 415 mm diameter wheels requiring Michelin TRX tyres. A catalysed, lower compression ratio version of the car with the S38 engine (260 PS ) was introduced in the U.S. in 1987. All M6 cars came standard with a 25% rear limited slip differential. U.S. models included additional comforts that were usually optional on models sold in Europe such as Nappa leather power seats and a dedicated rear A/C unit with a centre beverage chiller.  4,088 M635CSi cars were built between 1983 and 1988 with 1,767 U.S. bound, badges as the M6.

Produced initially purely as a homologation special, the E30 generation M3 achieved far greater levels of interest than ever imagined, and the rest, as they say, is history. Based on the 1986 model year E30 3 Series, the car was initially available with the 2 door body and was later offered as a convertible bodies. The E30 M3 used the BMW S14 engine. The first iteration of the road car engine produced 195 PS with a catalytic converter and 200 PS without a catalytic converter in September 1989 power was increased to 215 PS with a catalytic converter. The “Evolution” model (also called “EVO2”) produced 220 PS. Other Evolution model changes included larger wheels (16 X 7.5 inches), thinner rear and side window glass, a lighter bootlid, a deeper front splitter and additional rear spoiler. Later the “Sport Evolution” model production run of 600 (sometimes referred as “EVO3”) increased engine displacement to 2.5 litres and produced 238 PS. Sport Evolution models have enlarged front bumper openings and an adjustable multi-position front splitter and rear wing. Brake cooling ducts were installed in place of front foglights. An additional 786 convertibles were also produced. The E30 M3 differed from the rest of the E30 line-up in many other ways. Although using the same basic unit-body shell as the standard E30, the M3 was equipped with 12 different and unique body panels for the purposes of improving aerodynamics, as well as “box flared” wheel-arches in the front and rear to accommodate a wider track with wider and taller wheels and tyres. The only exterior body panels the standard model 3 Series and the M3 shared were the bonnet, roof panel, sunroof, and door panels. The E30 M3 differed from the standard E30 by having a 5×120 wheel bolt pattern. The E30 M3 had increased caster angle through major front suspension changes. The M3 had specific solid rubber offset control arm bushings. It used aluminium control arms and the front strut tubes were changed to a design similar (bolt on kingpins and swaybar mounted to strut tube) to the E28 5 Series. This included carrying over the 5 series front wheel bearings and brake caliper bolt spacing. The rear suspension was a carry over from the E30. The E30 M3 had special front and rear brake calipers and rotors. It also has a special brake master cylinder. The E30 M3 had one of two Getrag 265 5-speed gearboxes. US models received an overdrive transmission while European models were outfitted with a dogleg version, with first gear being down and to the left, and fifth gear being a direct 1:1 ratio. Rear differentials installed included a 4.10:1 final-drive ratio for US models. European versions were equipped with a 3.15:1 final drive ratio. All versions were clutch-type limited-slip differentials with 25% lockup. To keep the car competitive in racing following year-to-year homologation rules changes, homologation specials were produced. These include the Evo 1, Evo 2, and Sport Evolution, some of which featured less weight, improved aerodynamics, taller front wheel arches (Sport Evolution; to further facilitate 18-inch wheels in DTM), brake ducting, and more power.

Development of the E36 began in 1981 and the exterior design was heavily influenced by aerodynamics, specifically the overall wedge shape, headlight covers and smaller wing mirrors. The lead designers were Pinky Lai and Boyke Boyer. The production version of the E36 was launched in October 1990, with press release in November and market launch in early 1991. The initial models were of the four-door sedan body style, and these were soon followed by the coupe, convertible and Touring, to replace their equivalent E30 generation cars. The early models had a mixed reception, with many feeling that the build quality was not as good as previously and the grey plastic bumpers drew particular criticism, but BMW steadily evolved the car to make among the best available in its class and sales rocketed still further beyond E30 levels. The number of engines offered during the model’s life was greater than ever before, and this was the first 3 Series to be available with a six-speed manual transmission (in the 1996 M3), a five-speed automatic transmission and a four-cylinder diesel engine. The multi-link rear suspension was also a significant upgrade as compared to the previous generations of the 3 Series. All-wheel drive was not available for the E36, unlike the previous (E30) and successive (E46) generations. Following the introduction of its successor, the E46 3 Series in 1998, the E36 began to be phased out and was eventually replaced in 1999.

The M3 model of the E90/E92/E93 3 Series range was powered by the BMW S65 V8 engine and was produced in sedan, convertible and coupé body styles. The E9x is the first and only standard production M3 powered by a V8 engine as its successor would revert to using a straight 6 engine. In the standard M3, the S65 engine rated at 420 PS (414 bhp) at 8,300 rpm and 400 Nm (295 lb/ft) at 3,900 rpm. Initially, the M3 was produced with a 6-speed manual transmission. In April 2008, the E90/E92/E93 M3 became the first BMW to be available with a dual-clutch transmission when the 7-speed Getrag “M-DCT” transmission was introduced as an option. The official 0 to 100 km/h (62 mph) acceleration times for the coupé and sedan are 4.6 seconds with the DCT transmission (4.8 seconds with the manual transmission) and 5.1 seconds for the convertible. The E90 and E92 versions received many positive reviews, including “the greatest all-around car in the world”, “the finest car on the market, period” and “the best, most complete car in the world”. The first body style to be introduced was the coupé, which was previewed at the 2007 Geneva Motor Show and introduced in production form at the 2007 Frankfurt Motor Show on 12 September. The coupé version uses a carbon fibre roof to reduce weight and lower the centre of gravity. In 2010, the coupé and convertible versions received a minor facelift, which included revised LED tail-lights and minor interior trim pieces but it did not get the updated headlights from the regular series. The E93 convertible version was introduced shortly after the coupé and uses a power retractable hardtop. The leather seats in the convertible version are treated with a coating to reflect sunlight, in order to reduce their tendency to become uncomfortably hot with the top down. A sedan version was introduced in 2008 and was the second (along with the E36) M3 by generation to be produced in a 4-door body style. The sedan has the same drivetrain and similar external styling as the coupé, however the lack of a carbon fibre roof contributes to a weight increase of 10 kg (22 lb) compared to an identically equipped coupé. The official kerb weights for the 2008 European-specification models (with manual transmission) are 1,580 kg (3,483 lb) for the coupé, 1,605 kg (3,538 lb) for the sedan and 1,810 kg (3,990 lb) for the convertible. Total production of the E9x M3 was 40,092 coupés, 16,219 convertibles and 9,674 sedans. Production of sedan models finished in 2011, with coupés remaining in production until July 5, 2013.

The M2 was first revealed in Need for Speed: No Limits on November 2015, before later premiering at the North American International Auto Show in January 2016. Production commenced in October 2015 and is only available as a rear-wheel drive coupé. The M2 is powered by the turbocharged 3.0-litre N55B30T0 straight-six engine producing 365 bhp at 6,500 rpm and 465 Nm (343 lb/ft) between 1,450–4,750 rpm, while an overboost function temporarily increases torque to 500 N⋅m (369 lb⋅ft). The M2 features pistons from the F80 M3 and F82 M4, and has lighter aluminium front and rear suspension components resulting in a 5 kg (11 lb) weight reduction. The M2 is available with a 6-speed manual or with a 7-speed dual-clutch transmission which features a ‘Smokey Burnout’ mode. 0-100 km/h acceleration times are 4.5 seconds manual transmission models and 4.3 seconds for models equipped with the 7-speed dual clutch transmission. Top speed is limited to 250 km/h (155 mph) but can be extended to 270 km/h (168 mph) with the optional M Driver’s package. The M2 Competition was introduced at the 2018 Beijing Auto Show and succeeded the standard M2 Coupé. Production began in July 2018. The M2 Competition uses the high performance S55 engine which is a variant of the 3.0-litre twin turbocharged straight six engine found in the F80 M3 and F82 M4. The engine features a redesigned oil supply system and modified cooling system from the BMW M4 with the Competition Package, and also features a gasoline particulate filter in certain European Union countries to reduce emissions. Compared to the standard M2, the S55 produces an additional 30 kW (40 hp) and 85 Nm (63 lb/ft), resulting in a larger and more sustained power output of 405 bhp between 5,370–7,200 rpm, and 550 N⋅m (406 lb⋅ft) at 2,350–5,230 rpm. The 0-100 km/h acceleration time is 4.4 seconds for six-speed manual transmission models, and 4.2 seconds for models with the 7-speed dual clutch transmission. Top speed is electronically limited to 250 km/h (155 mph), but the M Driver’s package can extend the limit to 280 km/h (174 mph) which is 10 km/h (6 mph) further than in the M2. The M2 Competition also has a carbon-fibre reinforced plastic strut bar, enlarged kidney grilles, and larger brake discs of 400 mm (15.7 in) in the front axle and 380 mm (15.0 in) in the rear axle. Because of the new engine and cooling system, the M2 Competition is 55 kg (121 lb) heavier than the standard M2 at 1,550 kg (3,417 lb) for manual transmission models and 1,575 kg (3,472 lb) for dual-clutch transmission models.

CATERHAM

The Caterham story is one of continual development, a four decade process of honing Colin Chapman’s original design, which is now 60 years old. Since 1973, when Graham Nearn’s Caterham cars took over the rights and manufacture of the fly-weight sportscars, it’s grown more power, better engines, more sophistication in both suspension and powertrains, as well – in some cases – as more space inside and certainly more creature comforts, all while preserving the original character. Caterham completed 42 of the heavier and not that well thought of Series 4 cars before deciding to concentrate on the classic Series 3 design, with a simple space frame chassis clothed in aluminium and glassfibre. At the time of the S3, the power unit was from Ford, with the Crossflow unit developing 84 bhp in GT form with a twin choke carburettor, though twin Webers were never far away. Sevens had started out with Ford side valve power, before the 948cc BMC A Series unit found its way into the car, followed by Ford’s new 1340cc and 1498cc engines, before the head redesign put the intake and the exhaust on opposite sides. When Ford discontinued the Kent engine in 1976, it caused something of a difficulty for Caterham, as this also meant the end of the Twin Cam and the BDR engines, of which Caterham had bought 500 in preceding years, and whilst the final pushrod engines came from South Africa, eventually the supply ran out and a new supplier was needed. At first the firm turned to Vauxhall’s 2 litre unit for the higher powered cars but when the found out that Rover were developing a new and sophisticated twin cam engine, which turned out to be the K Series unit, a deal was struck and the first K Series engined Caterhams appeared in 1991, once the multi-point injection version was available (the single point would have required a bonnet bulge which Caterham did not want). To get round the relative lack of torque, Caterham developed their own close ratio 6 speed gearbox which was lighter than the Ford unit they had been using, and which could cope with larger capacity and more powerful K Series units as Rover made them available. Caterham continued to develop the car throughout the 90s, starting to make their own steering racks among other changes. By the time the K Series and the 240 bhp Vauxhall engines in the HPC car came along, the interior had become plusher with a long cockpit option and a wider variant, the SV. There were now proper bucket seats instead of those with a plywood backrest and in 1996 the handbrake moved from under the dash to the transmission tunnel. This required extra tubing in the chassis, which made it 80% stiffer. The front suspension had gained a proper top wishbone and separate anti-roll bar, but the biggest change came with the adoption of de Dion rear suspension. The move was occasioned by a need to keep the rear wheels linked and parallel to each other, yet still as simple as possible, though the engineers harboured a desire for a fully independent rear end, which finally came about with the CSR version in 2004. This change improved the ride massively on bumpy roads and makes the car feel more planted. The collapse of Rover in 2005 meant the end for the K Series, so there was a switch back to Ford power, using the Sigma engine, which happily fits under the bonnet – something that few modern engines do as they are now often simply too tall. Adding more power is a law of diminishing returns with a Caterham, thanks to the aerodynamics, though there are now an array of different power outputs offered, but the most recent change was a new entry level model, which uses a 660cc Suzuki turbo triple, with a live axle and a similar power to weight ratio to the classic single carb Ford powered models of 30 years ago. However, these days you can get carpets, leather seats and full weather gear if you upgrade to an S pack. Caterham plan to continue to develop the car for as long as they can. To date they have built around 16,000 examples, and it is said that were you to gather 100 models together, you would not find two the same, even though, colour apart, many cars look very similar at a quick glance.

FERRARI

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 centre 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.

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. Launched in 2002, it is essentially an updated 550 Maranello featuring minor styling changes from Pininfarina. The 575M was replaced by the 599 GTB in the first half of 2006. Updates from the 550 included a redesigned interior and substantial mechanical improvements, including bigger brake discs, a larger and more powerful engine, improved weight distribution, refined aerodynamics and fluid-dynamics along with an adaptive suspension set-up (the four independent suspensions are also controlled by the gearbox, to minimize pitch throughout the 200-milliseconds shift time). Two six-speed transmissions were available, a conventional manual gearbox and, for the first time on a Ferrari V12, Magneti Marelli’s “F1” automated manual gearbox. The 575 model number refers to total engine displacement in cc, whilst the ‘M’ is an abbreviation of modificata (“modified”).

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

The Ferrari F12 Berlinetta (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 F12 Berlinetta has won the 2013 International Engine of the Year Award in the Best Performance category and Best Engine above 4.0 litres. The F12 Berlinetta was named “The Supercar of the Year 2012” by car magazine Top Gear. The F12berlinetta was replaced by the 812 Superfast in 2017

Also here was an example of the 458 Speciale, one 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.

FIAT

The first 124 Spider made its debut at the Turin Show in 1966, and continued in production until the mid 1980s, bearing its desginer, Pininfarina’s badges in later years when it remained popular in the American market. Early cars had 1400 and 1600cc engines, and these were gradually enlarged first 1800cc and then 2 litre, with fuel injection being added for more power and emissions compliance during the 1970s. Fiat spotted the potential of the car for more than just boulevard cruising, though, so in November 1972 they announced the Fiat Abarth 124 Rally, an overtly sporting version. Its main purpose was to receive FIA homologation in the special grand touring cars (Group 4) racing class, and replace the 1.6-litre Fiat Sport Spider rally car which had been campaigned. At the time, the 124 had already won the 1972 European Rally Championship at the hands of Raffaele Pinto and Gino Macaluso. The 124 Rally was added to the Sport Spider range, which included the 1600 and 1800 models; the first 500 examples produced were earmarked for the domestic Italian market. Amongst the most notable modifications over the standard spider there were independent rear suspension, engine upgrades, lightweight body panels, and a fixed hard top. In place of the usual rear solid axle, there was a Chapman-type McPherson strut independent suspension, supplemented by a longitudinal torque arm. At the front a radius rod on each side was added to the standard double wishbones. The Abarth-tuned type 132 AC 4.000 1.8-litre, twin-cam engine was brought from the standard 118 to 128 PS DIN by replacing the standard twin-choke carburettor with double vertical twin-choke Weber 44 IDF ones, and by fitting an Abarth exhaust with a dual exit exhaust The 9.8:1 compression ratio was left unchanged. The transmission was the all-synchronised 5-speed optional on the other Sport Spider models, and brakes were discs on all four corners. Despite the 20 kg (44 lb) 4-point roll bar fitted, kerb weight was 938 kg (2,068 lb), roughly 25 kg (55 lb) less than the regular 1.8-litre Sport Spider. The bonnet, boot lid and the fixed hard top were fibreglass, painted matt black, the rear window was perspex and the doors aluminium. Front and rear bumpers were deleted and replaced by simple rubber bumperettes. A single matte black wing mirror was fitted. Matte black wheel arch extensions housed 185/70 VR 13 Pirelli CN 36 tyres on 5.5 J × 13″ 4-spoke alloy wheels. Inside, the centre console, rear occasional seats, and glovebox lid were eliminated; while new features were anodised aluminium dashboard trim, a small three-spoke leather-covered Abarth steering wheel, and Recaro corduroy-and-leather bucket seats as an extra-cost option. The car carried Fiat badging front and rear, Abarth badges and “Fiat Abarth” scripts on the front wings, and Abarth wheel centre caps. Only three paint colours were available: Corsa red, white, and light blue.  Seen here was an early AS series car.

FORD

Using the project name of “Archbishop”, management at Ford of Britain in Dagenham created a family-sized car which they could sell in large numbers. The chief designer was Roy Brown Jr., the designer of the Edsel, who had been banished to Dagenham following the failure of that car. The car was designed to be economical, cheap to run and easy and inexpensive to produce in Britain. The front-wheel drive configuration used by Ford of Germany for the new Ford Taunus P4, a similarly sized model, was rejected in favour of traditional rear-wheel drive layout. Aimed at buyers of the Morris Oxford Farina and Vauxhall Victor,  the car was launched as the Consul Cortina was launched on 20 September 1962.  with a 1,198 cc three-bearing engine, which was an enlarged version of the 997 cc engine then fitted in the Ford Anglia. A few months later, in January 1963, the Cortina Super was announced with a five-bearing 1,498 cc engine. Versions of the larger engine found their way into subsequent variations, including the Cortina GT which appeared in spring 1963 with lowered suspension and engine tuned to give a claimed output of 78 bhp ahead of the 60 bhp claimed for the Cortina 1500 Super. The engines used across the Mark I range were of identical design, differing only in capacity and setup. The formula used was a four-cylinder pushrod design that came to be known as the “pre-crossflow” version as both inlet and exhaust ports were located on the same side of the head. The most powerful version of this engine (used in the GT Cortina) was 1,498 cc and produced 78 bhp. This engine contained a different camshaft profile, a different cast of head featuring larger ports, tubular exhaust headers and a Weber double barrel carburettor. Advertising of the revised version, which appeared at the London Motor Show in October 1964, and which dropped the Consul name from its official designation, made much of the newly introduced “Aeroflow” through-flow ventilation, evidenced by the extractor vents on the rear pillars. A subsequent test on a warm day involving the four different Cortina models manufactured between 1964 and 1979 determined that the air delivery from the simple eyeball outlets on the 1964 Mark I Cortina was actually greater than that on the Mark II, the Mark III or the Mark IV. The dashboard, instruments and controls were revised, for the second time, having already been reworked in October 1963 when round instruments replaced the strip speedometer with which the car had been launched: twelve years later, however, the painted steel dashboard, its “knobs scattered all over the place and its heater controls stuck underneath as a very obvious afterthought” on the 1964 Mark I Cortina was felt to have aged much less well than the car’s ventilation system. It was also in 1964 that front disc brakes became standard across the range.  The Mark 1 Cortina was available as a two-door and four-door saloon, as well as in five-door estate (from March 1963) forms. Standard, Deluxe, Super, and GT trims were offered but not across all body styles. Early Standard models featured a simple body coloured front grille, earning it the nickname ‘Ironbar’. Since this version cost almost the same as the better equipped Deluxe it sold poorly and is very rare today. Options included heater and bench seat with column gearchange. Super versions of the estates offered the option of simulated wood side and tailgate trim. In an early example of product placement many examples of the brand new Cortina featured as “Glamcabs” in the comedy film Carry On Cabby.

Sporting Escorts appeared only a matter of months after the launch of the regular 1100 and 1300cc cars. The first of these was a higher performance version designed for rallies and racing, the Escort Twin Cam. Built for Group 2 international rallying, it had an engine with a Lotus-made eight-valve twin camshaft head fitted to the 1.5 L non-crossflow block, which had a bigger bore than usual to give a capacity of 1,557 cc. This engine had originally been developed for the Lotus Elan. Production of the Twin Cam, which was originally produced at Halewood, was phased out as the Cosworth-engined RS1600 production began. The most famous edition of the Twin Cam was raced on behalf of Ford by Alan Mann Racing in the British Saloon Car Championship in 1968 and 1969, sporting a full Formula 2 Ford FVC 16-valve engine producing over 200 hp. The Escort, driven by Australian driver Frank Gardner went on to comfortably win the 1968 championship. The Mark I Escorts became successful as a rally car, and they eventually went on to become one of the most successful rally cars of all time with arguably the Escort’s greatest victory in the 1970 London to Mexico World Cup Rally, co-driven by Finnish legend Hannu Mikkola and Swedish co-driver Gunnar Palm. This gave rise to the Escort Mexico, which had a 1600cc “crossflow”-engined, as a special edition road version in honour of the rally car. Introduced in November 1970, 10,352 Mexico Mark I’s were built. In addition to the Mexico, the RS1600 was developed with a 1,601 cc Cosworth BDA which used a Crossflow block with a 16-valve Cosworth cylinder head, named for “Belt Drive A Series”. Both the Mexico and RS1600 were built at Ford’s Advanced Vehicle Operations (AVO) facility located at the Aveley Plant in South Essex. As well as higher performance engines and sports suspension, these models featured strengthened bodyshells utilising seam welding in places of spot welding, making them more suitable for competition. After updating the factory team cars with a larger 1701 cc Cosworth BDB engine in 1972 and then with fuel injected BDC, Ford also produced, in the autumn of 1973, an RS2000 model as an alternative to the somewhat temperamental RS1600, featuring a 2.0 litre Pinto OHC engine. This also clocked up some rally and racing victories; and pre-empted the hot hatch market as a desirable but affordable performance road car. Like the Mexico and RS1600, this car was produced at the Aveley plant.

The squarer-styled Mark II Escort appeared in January 1975. The first production models had rolled off the production lines on 2 December 1974. Unlike the first Escort (which was developed by Ford of Britain), the second generation was developed jointly between the UK and Ford of Germany. Codenamed “Brenda” during its development, it used the same mechanical components as the Mark I. The 940 cc engine was still offered in Italy where the smaller engine attracted tax advantages, but in the other larger European markets in Europe it was unavailable. The estate and van versions used the same panelwork as the Mark I, but with the Mark II front end and interior. The car used a revised underbody, which had been introduced as a running change during the last six months production of the Mark I. Rear suspension still sat on leaf springs though some contemporaries such as the Hillman Avenger had moved on to coil springs. The car came in for criticism for its lack of oddments space, with a glove compartment only available on higher end models, and its stalk-mounted horn. The “L” and “GL” models (2-door, 4-door, estate) were in the mainstream private sector, the “Sport”, “RS Mexico”, and “RS2000” in the performance market, the “Ghia” (2-door, 4-door) for a hitherto untapped small car luxury market, and “base / Popular” models for the bottom end. Panel-van versions catered to the commercial sector. The 1598 cc  engine in the 1975 1.6 Ghia produced 84 hp with 92 lb/ft torque and weighed 955 kg (2105 lb). A cosmetic update was given in 1978 with L models gaining the square headlights (previously exclusive to the GL and Ghia variants) and there was an upgrade in interior and exterior specification for some models. Underneath a wider front track was given. In 1979 and 1980 three special edition Escorts were launched: the Linnet, Harrier and Goldcrest. Production ended in Britain in August 1980, other countries following soon after. Spotted here was an RS2000.

A sporting version of Ford’s front wheel drive Escort was announced at the same time as the “cooking” 1.1, 1.,3 and 1,6 litre cars in October 1980. This was the XR3, and it came initially with a carb fed 1.6 litre engine generating 105 bhp and had a four speed gearbox. Fuel injection finally arrived in October 1982 (creating the XR3i), eight months behind the limited edition (8,659 examples), racetrack-influenced RS 1600i. The Cologne-developed RS received a more powerful engine with 115 PS, thanks to computerised ignition and a modified head as well as the fuel injection. For 1983, the XR3i was upgraded to 115bhp thanks to the use of fuel injection and a five speed transmission had been standardised. Both variants proved very popular, getting a significant percentage of Escort sales and also as a slightly more affordable alternative to a Golf GTi. For those for whom the performance was not quite enough, Ford had an answer, with the the RS Turbo. This 132 PS  car was shown in October 1984, as a top of the range car, offering more power than the big-selling XR3i and the limited production RS1600i. Going on sale in the spring of 1985, it proved to be somewhat of a disappointment, with the chassis coming in for severe criticism.  The RS Turbo Series 1 was only marketed in a few European nations as production was limited to 5,000 examples, all in white. They were well equipped, with the alloy wheels from the limited production RS 1600i, Recaro seats, and a limited slip differential.

The Ford Sierra is a mid-size car or large family car that was built by Ford Europe from 1982 to 1993. It was designed by Uwe Bahnsen, Robert Lutz and Patrick le Quément. The code used during development was “Project Toni”. Its name came from the Spanish word for mountain range. The Ford Sierra was first unveiled on 22 September 1982 at the British International Motor Show hosted at the NEC in Birmingham, shortly followed by the Salon de l’Automobile in Paris on 30 September 1982. Sales started on 15 October 1982, replacing the Ford Taunus TC3 (UK: Ford Cortina Mark V). Its aerodynamic styling was ahead of its time and as such, many conservative buyers (including company car drivers) did not take fondly to the Taunus’s/Cortina’s replacement. This was also due to the fact that the Sierra was not available as a saloon, in contrast to the Taunus/Cortina. A saloon model debuted in 1987 with the introduction of the facelifted Sierra. It was mainly manufactured in Germany, Belgium, and the United Kingdom, although Sierras were also assembled in Ireland, Argentina, Venezuela, South Africa and New Zealand. By 1978, Ford Europe was working on a new mid-range model to replace the Cortina/Taunus during the early 1980s, working under the codename “Project Toni”. Although still popular with buyers, the outgoing Cortina/Taunus was essentially a 12-year old design by the time of the Sierra’s launch; despite the TC2 shape launching in 1976, and the mildly reworked TC3/Mk5 three years later, both were merely a reskinned version of the 1970 TC/Mk3 with few major mechanical changes in that time. Ford’s future model policy and styling direction had already been shown with the Escort III two years earlier, in that its conventionally styled saloons of the 1970s would be replaced by hatchbacks with advanced aerodynamic styling. Ford had confirmed during 1981, a year before the Sierra’s official launch, that its new mid-range car would carry the Sierra name, signalling the end of the Taunus and Cortina nameplates after 43 years and nine generations respectively 20 years and five generations. In September that year, it had unveiled the Probe III concept car at the Frankfurt Motor Show, hinting at what the new car would look like when the final product was unveiled 12 months later. At first, many found the design blob-like and difficult to accept after being used to the sharp-edged, straight-line three-box styling of the Taunus/Cortina, and it was nicknamed “the jellymould”. The shape served a purpose though, producing a drag coefficient of 0.34, a significant improvement over the boxy outgoing Taunus’s/Cortina’s 0.45. This aerodynamic design was key for reducing fuel consumption according to Ford, and was even used as compensation for the V6-engines. The interior was more conventional, although Ford took a page from BMW by angling the centre of the dashboard towards the driver. Sales were slow in the first months – the situation being exacerbated by heavy discounting by Ford dealers of surplus Cortina stock from the autumn of 1982 onwards, with more than 11,000 new Cortinas being registered in 1983. However in 1983, its first full year of sales, the Sierra managed nearly 160,000 sales in Britain, outsold only by the smaller Escort. Ford had also launched the more conservatively designed Escort-based Orion saloon that year, which found favour with buyers who would otherwise have been the Sierra’s target customers. In West Germany, it was proving very popular from an early stage; within months of its launch, it was reportedly achieving treble the number of sales that the Taunus had been attaining – though in West Germany, the Taunus had not been quite as popular or iconic as its Cortina equivalent had been in Britain. It was later in the Sierra’s life that the styling began to pay off; ten years after its introduction, the Sierra’s styling was not nearly as outdated as its contemporaries, even though all major competitors were newer designs, though the Sierra had been tweaked on several occasions and many new engines had been added. The most notable changes came at the autumn of 1987, with a major facelift and the addition of a 4-door saloon (UK: Sapphire). As other manufacturers adopted similar aerodynamic styling, the Sierra looked more normal. At its peak, it was Britain’s second best selling car in 1983, 1988 and 1989, and was still Britain’s fifth best selling car in 1992. Its best year was 1989, when more than 175,000 were sold. However, it was outsold by the Vauxhall Cavalier in MK2 form during 1984 and 1985, and then from 1990 until its demise by the MK3 Cavalier. Nevertheless, it comfortably outsold its second key rival, the Austin Montego, which was launched in April 1984. Between 1985 and 1988, the Sierra faced fresh competition in Europe from the likes of the Renault 21 and Peugeot 405, while Japanese carmaker Nissan was producing its Bluebird model in Britain from 1986. Early versions suffered from crosswind stability problems, which were addressed in 1985 with the addition of “strakes” (small spoilers) on the rear edge of the rubber seals of the rear-most side windows. These shortcomings saw a lot of press attention, and contributed to early slow sales, when it was outsold by its key rival the Vauxhall Cavalier in 1984 and 1985. Other rumours that the car hid major crash damage (in part true, as the new bumper design sprung back after minor impact and couldn’t be “read” to interpret major damage) also harmed the car’s reputation. This reached near-hysterical heights in its early months on sale, with UK press making a report that Ford would reintroduce the previous Cortina model out of desperation. These reports were swiftly denied by Ford. However, sales began to rise during 1983, and it finished as Britain’s second best selling car behind the Escort. After being outsold by the Cavalier for the next two years, it regained its lead of the market sector in Britain during 1986, and a refreshed range (with more engine options as well as the introduction of a saloon) enjoyed a surge in sales from 1987, though the MK3 Cavalier finally outsold it in 1990. Even in 1992, the Sierra was still Britain’s fifth best selling car. It was nicknamed “the salesman’s spaceship” on account of its status as a popular fleet car in Britain. In contrast to the Sierra’s groundbreaking exterior design, its drivetrain was conservatively engineered, retaining rear-wheel drive and the same engines and transmissions as the Cortina/Taunus which were effectively 12 years old as they were first used on the TC1/MkIII generation in 1970. Much of this was done to appease the important fleet market which was wary of complexity. However, there was much modification; for example the engines were fitted with breakerless ignition, improved carburettors and the option of fuel injection, whilst 5-speed transmissions were now available. Most competitors were already switched to front-wheel drive around that time. Ford claimed however this set-up was required to offer V6-engines, which had to contribute to the Sierra’s driving comfort. New for the Sierra was a diesel engine, although the engine itself wasn’t new at all. Similar to the Ford Granada, Ford used an “Indenor”-engine which was designed by Peugeot in the 1950s. While the Granada was offered with 1.9, 2.1 and 2.5 diesels, the Sierra unit had a displacement of 2.3 litre. This engine was replaced only in 1989 by an all-new 1.8 litre turbodiesel, developed by Ford itself. The Sierra had a four-speed manual gearbox as standard, with a five-speed as option but standard on the 2.3D and 2.3 V6. At a time when the rival Vauxhall Cavalier was offered with a five-speed, this led to some critics commenting that the Sierra was somewhat underpowered. In the mid-1980s, many smaller cars (some even two segments smaller) featured five-speed gearboxes as standard. The chassis, however, was more sophisticated than the Cortina/Taunus, with fully independent suspension on both axles. The rear suspension was essentially carried over from the Granada, with trailing arms and coil springs mounted on a tubular sub-frame which also provided location for the final drive/differential housing driving the axle shafts. The front suspension dispensed with the Cortina/Taunus’ double wishbones in favour of a scaled-up version of the Fiesta and Escort/Orion’s layout with MacPherson struts, lower locating arms and anti-roll bars. One of the most striking design features of the Sierra was its closed front panel instead of a grille, which was later also to be found on the 1985 Ford Taurus. The air intake was situated below the front bumper, making the Sierra a so-called ‘bottom breather’. The headlights were integrated in this front panel while the indicators were mounted in the bumper within a combined unit with the foglights. However, this set-up was only present on the top-of-the-line “Ghia”-trim as well on the later introduced XR4i sport model. The other Sierra models had a more traditional front end with a two-bar grille between the headlights, being unpainted on the base model. These models had the indicators in the bumper as well, although being slimmer but wider and without the foglights. Both the Ghia and XR4i had wide headlights with two lenses while the other models had smaller lights with a single lens. For the 1985 model year, all the lower-spec models, except the base model, adopted the Ghia and XR4i’s front grille and headlight treatment. However, the second lens of the lower-spec models had no actual light within it. On the Ghia and XR4i this lens contained additional high beam lamps. The South-African XR8 model’s front end was similar to the XR4i’s but featured a small grille between the headlights. The rear lights of the Ghia, as well as the very early XR4i’s, were the same shape and layout as other models, but featured tiny horizontal black strakes on the lenses to give the impression that they were smoked. The car was replaced by the Mondeo in Europe in April 1993, though stocks lasted for about two years afterwards. The Sierra remained a popular second-hand buy and common sight on British roads until well beyond the year 2000.

The Sierra RS Cosworth model. a very sporting  version of Ford’s upper-medium sized family car, was built by Ford Europe from 1986 to 1992, the result of a Ford Motorsport project with the purpose of producing an outright winner for Group A racing in Europe. The project was defined in the spring of 1983 by Stuart Turner, then recently appointed head of Ford Motorsport in Europe, who had realised right away that Ford was no longer competitive in this area. Turner got in touch with Walter Hayes, at the time the vice-president of public relations at Ford, to get support for the project. Hayes had earlier been the driving force behind the development of the Ford GT40 that won Le Mans in 1966, and the Cosworth DFV engine that brought Ford 154 victories and 12 world championships in Formula One during the 1960s and 1970s. Hayes found the project very appealing and promised his full support. Turner then invited Ken Kohrs, vice-president of development, to visit Ford’s longtime partner, the automotive company Cosworth, where they were presented a project developed on Cosworth’s own initiative, the YAA engine. This was a twin cam, 16-valve engine based on Ford’s own T88 engine block, better known as the Pinto. This prototype proved an almost ideal basis for the engine Turner needed to power his Group A winner. Therefore, an official request for a turbocharged version (designated Cosworth YBB) capable of 180 HP on the street and 300 HP in race trim, was placed. Cosworth answered positively, but they put up two conditions: the engine would produce not less than 204 HP in the street version, and Ford had to accept no fewer than 15,000 engines. Turner’s project would only need about 5,000 engines, but Ford nevertheless accepted the conditions. The extra 10,000 engines would later become one of the reasons Ford also chose to develop a four door, second generation Sierra RS Cosworth. To find a suitable gearbox proved more challenging. The Borg-Warner T5, also used in the Ford Mustang, was chosen, but the higher revving nature of the Sierra caused some problems. Eventually Borg-Warner had to set up a dedicated production line for the gearboxes to be used in the Sierra RS Cosworth. Many of the suspension differences between the standard Sierra and the Cosworth attributed their development to what was learned from racing the turbocharged Jack Roush IMSA Merkur XR4Ti in America and Andy Rouse’s successful campaign of the 1985 British Saloon Car Championship. Much of Ford’s external documentation for customer race preparation indicated “developed for the XR4Ti” when describing parts that were Sierra Cosworth specific. Roush’s suspension and aerodynamics engineering for the IMSA cars was excellent feedback for Ford. Some production parts from the XR4Ti made their way into the Cosworth such as the speedometer with integral boost gauge and the motorsport 909 chassis stiffening plates. In April 1983, Turner’s team decided on the recently launched Sierra as a basis for their project. The Sierra filled the requirements for rear wheel drive and decent aerodynamic drag. A racing version could also help to improve the unfortunate, and somewhat undeserved, reputation that Sierra had earned since the introduction in 1982. Lothar Pinske, responsible for the car’s bodywork, demanded carte blanche when it came to appearance in order to make the car stable at high speed. Experience had shown that the Sierra hatchback body generated significant aerodynamic lift even at relatively moderate speed. After extensive wind tunnel testing and test runs at the Nardò circuit in Italy, a prototype was presented to the project management. This was based on an XR4i body with provisional body modifications in fibreglass and aluminium. The car’s appearance raised little enthusiasm. The large rear wing caused particular reluctance. Pinske insisted however that the modifications were necessary to make the project successful. The rear wing was essential to retain ground contact at 300 km/h, the opening between the headlights was needed to feed air to the intercooler and the wheel arch extensions had to be there to house wheels 10” wide on the racing version. Eventually, the Ford designers agreed to try to make a production version based on the prototype. In 1984, Walter Hayes paid visits to many European Ford dealers in order to survey the sales potential for the Sierra RS Cosworth. A requirement for participation in Group A was that 5,000 cars were built and sold. The feedback was not encouraging. The dealers estimated they could sell approximately 1,500 cars. Hayes did not give up, however, and continued his passionate internal marketing of the project. As prototypes started to emerge, dealers were invited to test drive sessions, and this increased the enthusiasm for the new car. In addition, Ford took some radical measures to reduce the price on the car. As an example, the car was only offered in three exterior colours (black, white and moonstone blue) and one interior colour (grey). There were also just two equipment options: with or without central locking and electric window lifts. The Sierra RS Cosworth was first presented to the public at the Geneva Motor Show in March 1985, with plans to release it for sale in September and closing production of the 5,000 cars in the summer of 1986. In practice, it was launched in July 1986. 5545 were manufactured in total of which 500 were sent to Tickford for conversion to the Sierra three-door RS500 Cosworth. The vehicles were manufactured in right hand drive only, and were made in Ford’s Genk factory in Belgium. Exactly 500 RS500s were produced, all of them RHD for sale in the UK only – the biggest market for this kind of Ford car. It was originally intended that all 500 would be black, but in practice 56 white and 52 moonstone blue cars were produced.To broaden the sales appeal, the second generation model was based on the 4 door Sierra Sapphire body. It was launched in 1988, and was assembled in Genk, Belgium, with the UK-built Ford-Cosworth YBB engine. Cylinder heads on this car were early spec 2wd heads and also the “later” 2wd head which had some improvements which made their way to the 4X4 head. Suspension was essentially the same with some minor changes in geometry to suit a less aggressive driving style and favour ride over handling. Spindles, wheel offset and other changes were responsible for this effect. Approximately 13,140 examples were produced during 1988-1989 and were the most numerous and lightest of all Sierra Cosworth models. Specifically the LHD models which saved weight with a lesser trim level such as manual rear windows and no air conditioning. In the UK, the RHD 1988-1989 Sierra Sapphire RS Cosworth is badged as such with a small “Sapphire” badge on the rear door window trims. All 1988-1989 LHD models are badged and registered as a Sierra RS Cosworth with no Sapphire nomenclature at all. “Sapphire” being viewed as a Ghia trim level that saw power rear windows, air conditioning and other minor options. Enthusiasts of the marque are mindful of this and will describe the LHD cars by their body shell configuration, 3 door or 4 door. As the Sapphire Cosworth was based on a different shell to the original three-door Cosworth, along with its more discreet rear wing, recorded a drag co-efficient of 0.33, it registered slightly better performance figures, with a top speed of 150 mph and 0-60 of 6.1 seconds, compared to the original Cosworth. In January 1990,  the third generation Sierra RS Cosworth was launched, this time with four wheel drive. As early as 1987, Mike Moreton and Ford Motorsport had been talking about a four wheel drive Sierra RS Cosworth that could make Ford competitive in the World Rally Championship. The Ferguson MT75 gearbox that was considered an essential part of the project wasn’t available until late 1989 however. Ford Motorsport’s desire for a 3-door “Motorsport Special” equivalent to the original Sierra RS Cosworth was not embraced. The more discreet 4-door version was considered to have a better market potential. It was therefore decided that the new car should be a natural development of the second generation, to be launched in conjunction with the face lift scheduled for the entire Sierra line in 1990. The waiting time gave Ford Motorsport a good opportunity to conduct extensive testing and demand improvements. One example was the return of the bonnet louvres. According to Ford’s own publicity material, 80% of the engine parts were also modified. The improved engine was designated YBJ for cars without a catalyst and YBG for cars with a catalyst. The latter had the red valve cover replaced by a green one, to emphasise the environmental friendliness. Four wheel drive and an increasing amount of equipment had raised the weight by 100 kg, and the power was therefore increased to just about compensate for this. The Sierra RS Cosworth 4×4 received, if possible, an even more flattering response than its predecessors and production continued until the end of 1992, when the Sierra was replaced by the Mondeo. The replacement for the Sierra RS Cosworth was not a Mondeo however, but the Escort RS Cosworth. This was to some extent a Sierra RS Cosworth clad in an “Escort-like” body. The car went on sale in May 1992, more than a year after the first pre-production examples were shown to the public, and was homologated for Group A rally in December, just as the Sierra RS Cosworth was retired. It continued in production until 1996. The Sierra and Sapphire Cosworths were undoubted performance bargains when new, but they also gained a reputation both for suffering a lot of accidents in the hands of the unskilled and also for being among the most frequently stole cars of their generation. These days, though, there are some lovely and treasured examples around and indeed you are far more likely to see a Cosworth version of the Sierra than one of the volume selling models.

A completely new Fiesta, codenamed BE-13 was unveiled at the end of 1988 and officially went on sale in February 1989. The car was based on a new platform ditching the old car’s rear beam axle for a semi-independent torsion beam arrangement and looked radically different, addressing the principal weakness of the previous generation – the lack of a 5-door derivative, something that was by then available in its major rivals such as the Fiat Uno, Peugeot 205 and 106 and Opel Corsa/Vauxhall Nova. The other main change was to the running gear – the improved HCS (High Compression Swirl) version of the Kent/Valencia powerplant. The CVH units from the second generation were carried over largely unmodified. The diesel engine was enlarged to a 1.8L capacity. As for sports models, the XR2i was launched in August 1989 with an eight-valve CVH (standing for “compound valve-angle hemispherical combustion chamber”) engine with 104 PS. This was the first Fiesta to have a fuel-injected engine. This was then replaced by a Zetec 16 valve version in 1992, which also saw the RS Turbo being supplanted by the RS1800 as the CVH engine was being phased out. The RS1800 shared its 1.8 litre Zetec fuel-injected engine with the 130 bhp version of the then current Ford Escort XR3i and had a top speed of 125 mph. The XR2i name was also dropped in early 1994, and the insurance-friendly “Si” badge appeared in its place on a slightly less sporty-looking model with either the 1.4 L PTE (a development of the CVH) or the 1.6 L Zetec engine.

The Ford Escort RS Cosworth is a sports derivative and rally homologation special of the fifth generation European Ford Escort. It was designed to qualify as a Group A car for the World Rally Championship, in which it competed between 1993 and 1998. It was available as a road car from 1992–96 in very limited numbers. Ford developed the car around the chassis and mechanicals of its spiritual predecessor, the Sierra Cosworth to accommodate the larger Cosworth engine and transmission, whilst clothing it in Escort body panels to make it resemble the standard car. Designed under the guidance of Rod Mansfield and John Wheeler of Ford’s SVO department, the styling was carried out during 1989, a year before the standard Escort was launched, by Stephen Harper at MGA Developments in Coventry. The spoiler was added by Frank Stephenson, who originally proposed a three-deck piece. The body tooling was created by coachbuilders Karmann at their facility in Rheine, Germany, where the cars were manufactured. Changes were made to the engine management system and a new turbocharger was fitted. Permanent four wheel drive with a 34/66% front/rear split came courtesy of an uprated five speed gearbox as used in the Sierra Cosworth. Recaro sports seats came as a standard fitment. Later production models were available without the oversize tail spoiler although by far the majority were still ordered with it. Like its Sierra predecessor, they are commonly nicknamed “Cossie” by enthusiasts. The car’s top speed was 150 mph, which rivalled lower-end supercars including the Audi Quattro, BMW M3, Nissan 300ZX and Toyota Supra, and comfortably outperformed traditional “hot hatchbacks” like the Volkswagen Golf GTI. It was much faster than the 126 mph which the Escort RS2000 and earlier Escort RS Turbo were capable of. Two versions were produced. The initial 2,500 units were “homologation specials” used to get the FIA accreditation for entry into the World Rally Championship. They were fitted with a Garrett T3/T04B turbocharger. Among these initial units, a handful were badged as Motorsport versions, these lacked certain refinements such as a sunroof and sound deadening. The initial cars included features that, although they made the Cosworth a more effective car, did not enhance it as a road vehicle, and once the rules were satisfied Ford attempted to make the car less temperamental and easier to drive under normal conditions. The second generation, starting production from late 1994, were fitted with a Garrett T25 turbocharger, a smaller unit which reduced turbo lag and increased usability in everyday driving situations. With these later models, the ‘whale tail’ spoiler became a delete option. . The Escort Cosworth was a rare car, with 7,145 vehicles produced from the start of production on 19 February 1992 until the last car rolled out of the factory on 12 January 1996.

Ford did not make the same mistake with the Focus as they had with its predecessor, so even the ordinary models were good to drive. There was a long wait for a truly sporting flagship, but when it arrived, in late 2002, the Focus RS proved to be rather special. Originally it was to be released as the Racing Focus, however after the poor selling Racing Puma, Ford decided to revive the RS badge. The car was largely built on its own assembly line in Ford’s Saarlouis plant, with some additional specialist off-line assembly performed by the ACÜ group at Überhern. The RS was offered all over Europe, with production limited to 4501 units. 2147 of these were sold in the United Kingdom, by far its largest of the 21 markets where it was available. The development of the Focus RS was undertaken by a mixed team of mainstream Ford engineers (not SVE or the TeamRS group which replaced it later on) and Tickford Engineering in Milton Keynes, United Kingdom. More bespoke than the prior Focus ST170,  the Focus RS upgraded or replaced 70% of the standard Focus mechanicals. The turbocharged straight-4 engine produced a minimum of 212 bhp and 310 Nm (229 lb/ft) of torque, which was then mated to the 5-speed MTX-75 and not the Getrag transmission used in the ST 170. Mechanically, most notably, the car incorporated a Quaife automatic torque biasing differential to improve traction from the front-wheel drive setup. The steering used a similar quick-ratio rack as the ST170 while the brakes used fixed-caliper, four-piston Brembo units with 12.8 in discs at the front and single-piston floating calipers and 11.0 in discs at the back. Wheels were 18″ alloys specially developed by OZ Racing. The engine was heavily modified with forged aluminium pistons, hardened valve seats, sodium-filled exhaust valves, stainless steel exhaust system. The forced induction system comprised a Garrett turbocharger with a water-cooled charge air cooler and an electric water pump. To transmit the higher torque an upgraded AP clutch was used. It could generate a steady 0.98G in lateral acceleration due to racing parts such as Sachs dampers, lightweight O.Z Alloy Wheels and a Quaife ATB Differential. It would also allow 1.0G of braking force due to the standard Brembo braking system. The Focus RS was available in one metallic colour, Imperial Blue. The body looked similar to the standard Focus or to the ST170, although the RS featured unique front and rear bumper assemblies required for the wider wheel arches which accommodated the 65 mm (2.6 in) wider front track. Internally, the theme is blue and black with sections of blue leather trim on the door trim panels, the steering wheel and the Sparco seats which were trimmed in blue/black leather and Alcantara. A green starter button starts the engine. The instruments have a blue background and in place of the coolant temperature gauge, the RS was equipped with a boost pressure indicator (up to 1.5 bar). The gear lever knob, handbrake lever, and pedals were all custom made by Sparco. All-around performance was roughly equal or better to its other competitors, including hatchbacks such as the Honda Civic Type-R and some four-wheel drive cars in the same price field. Power was a diminished priority and the handling on a track, courtesy of the front differential, was considered by most observers to be its strongest characteristic. In a Top Gear review, Jeremy Clarkson noted that “it lacks the straightforward oomph of a Subaru Impreza. […] The reason it was quick round our track is simple: this car handles like it’s in a cartoon.” Clarkson and other motor journalists also commented on the car’s torque steer on bumpy British roads. Well preserved examples – and that’s not all of them, by any means, now – are worth decent money and will likely increase in value over time.

The regular second generation Focus cars were released in late 2004. An ST version followed very quickly, and for a long time, Ford maintained that was the only sporty Focus there was going to be. Finally, on December 17, 2007 Ford of Europe confirmed that a Mk 2 Focus RS would be launched in 2009, with a concept version due in mid-2008, with an upgraded Duratec ST engine with 305PS Duratec RS, gearbox, suspension, and LSD. In 2008, Ford revealed the new Focus RS in “concept” form at the British International Motor Show. Contrary to numerous rumours and speculation, the RS was announced by Ford to have a conventional FWD layout. The Duratec RS engine was upgraded to produce 301 bhp and 325 lb/ft of torque. 0 to 100 km/h (62 mph) acceleration was quoted to be under 6 seconds. The RS used a modified Volvo -engineered 2,522cc five-cylinder engine found in the Focus ST. A larger Borg Warner K16 turbo now delivers up to 20.3-psi of boost. A new air-to-air intercooler has been developed as a complement, while the forged crankshaft, silicon-aluminium pistons, graphite-coated cylinder bores, 8.5:1 compression ratio and variable valve timing also up the power output. The car remained front wheel drive, but to reduce torque steer used a Quaife Automatic Torque Biasing LSD, and a specially designed MacPherson strut suspension at the front called RevoKnuckle, which provided a lower scrub radius and kingpin offset than traditional designs while avoiding the increased weight and complexity of double wishbone and multi-link suspension setups. Ford UK claim: “It’s as close as you’ll come to driving a full-spec rally car (Ford Focus RS WRC). The production car was finally unveiled on 5 January 2009. It looked very distinctive, as at the rear a large venturi tunnel and a dramatic rear spoiler created a purposeful look. It was available in three expressive exterior colours: Ultimate Green, Performance Blue and Frozen White. The ‘Ultimate’ Green was a modern reinterpretation of the classic 1970s Ford Le Mans Green of the Ford Escort RS1600 era.

Ford played much the same guessing game about whether there would be an RS version of the third generation Focus as they had done with the earlier versions. Production of the regular cars started in late 2010, but it was not until the 2015 Geneva Motor Show before the production ready MKIII Ford Focus RS was unveiled. It came packing the turbocharged 2.3-litre inline-four engine found in the Mustang EcoBoost. In the Focus RS, the engine itself produces 350 hp. Power is sent to all four wheels via Ford’s all-new Torque-Vectoring All-Wheel-Drive system with a rear drive unit designed by GKN, as well as upgraded suspension and brakes. As well as that, the new Focus RS will be fitted with Drive Modes – including an industry-first Drift Mode that allows controlled oversteer drifts – and Launch Control. The RS will boast a model specific aerodynamic package that helps to differentiate it from other Focus models. The RS is capable of accelerating to 100 km/h (62 mph) in 4.7 seconds. Sales finally started in mid 2016, with long waiting lists having been created, though Ford did eventually catch up with expanded production levels allowing them to meet the demand.

There has not been an RS version of the fourth generation Focus, despite rumours persisting for a while about such a car, so the sporting top of the range these days is the  ST and there was at least one of these here along with a number of other sporting Ford models.

Also here was an example of what is still in Europe the current Mustang, the seventh generation car which was launched in late 2022 in the US, having yet to arrive on our shores.

Like most GT40 type cars that you see, this is a replica rather than one of the rare originals from the 1960s. This one is an MDA GT40, and there is a complex history surrounding the firm who produced it. GT Racing has a history dating back to 1985 for specialist vehicle design and builds. Starting with high quality customer vehicles to specific chassis and body designs. Working for another quality GT40 car manufacturer G T Developments during 1988-1994 with over 380 built cars to its credit. Forming MDA in 1994 the customer list grew for individual car builds with a more demanding accuracy and design improvement. MDA GT40 LTD was started in 2003 and many more cars produced. In the World Recession in 2008 MDA GT40 LTD closed its doors due to economic pressure. Since then MDA have still supplied GT40 parts to existing customers and owners of other GT40 models and other Race car owners under the name of G T Racing. GT Racing supplies customers worldwide with unique automotive services. They are a GT40 specialist and can supply all parts including space frame chassis and original type body. They offer a wide range of GT40 items including their famous original tool made fuel filler caps, ZF top plate and many other accurate parts.

HILLMAN

Known internally at Rootes as the “Apex” project, the Imp was to be the group’s first post-Second World War small car. Its main rival on the home market was the BMC Mini, which preceded the Imp by almost four years. Launched in May 1963, much was expected of this promising small car, which was all-new and which was built in a new factory in Linwood in Scotland, far away from the rest of the Rootes Group’s facilities in the Coventry area. Conceived as a direct competitor to the BMC’s Mini, it adopted a different approach to packaging, with a space-saving rear-engine and rear-wheel-drive layout to allow as much luggage and passenger capacity as possible in both the rear and the front of the car. It used a unique opening rear hatch to allow luggage to be put into the back seat rest. In addition to its 875 cc all-aluminium power unit, adapted by Rootes from a Coventry Climax FWMA fire pump engine it was the first mass-produced British car to have an engine in the back and the first car to use a diaphragm spring clutch. The baulk-ring synchromesh unit for the transaxle compensated for the speeds of gear and shaft before engagement, which the Mini had suffered from during its early production years. It incorporated many design features which were uncommon in cars until the late 1970s such as a folding rear bench seat, automatic choke and gauges for temperature, voltage and oil pressure. At launch it was considered advanced for the time, but reliability problems quickly harmed its reputation, which led to the Rootes Group being taken over by Chrysler Europe in 1967. Over the life of the car, Rootes (and later Chrysler UK) produced four body styles. The original saloon was introduced in May 1963 and ran through to the end of production in 1976. It has an opening rear window, making it effectively a hatchback. The opening rear window was intended to make it easier to load the small luggage area behind the fold-down rear seat. The fold-down nature of the rear seat was itself unusual in small car design at the time, being more often associated with larger upmarket estate cars. In 1965 a van badged as the “Commer Imp” was introduced. A coupe, the Imp Californian, was introduced in 1967 at the same time as the van’s pressings were used to create an estate car, badged “Hillman Husky”. Several estate car prototypes using the saloon body with extended rooflines were tried, but never offered to the public. Instead, buyers choosing the estate had to settle for a van-derived car with somewhat unusual styling. Both the van and estate ceased production in 1970. In an attempt to interest a wider public when sales figures fell well short of the intended 100,000 cars per annum, several badge-engineered derivatives, such as the luxury Singer Chamois (launched October 1964), and the Sunbeam Sport (launched October 1966), with a more powerful twin-carburettor engine, were offered with varying degrees of success. For marketing reasons the Singer variants were sold as Sunbeams in many export markets, even before May 1970 when the Singer marque was discontinued altogether by Chrysler UK. In some markets, such as France, the “Sunbeam” name was used on all British Rootes products, including the Imp and the Husky.The coupe bodyshell is similar to the standard body but features a more shallow-raked windscreen and rear window which, unlike that on the standard bodied cars, can not be opened. The attempt at a more sporty design did not translate into better acceleration or top speed figures and the aerodynamics of the standard saloon are actually slightly better. The new body style made its first appearance at the Paris Motor Show in October 1967, with the introduction of the sporting Sunbeam Stiletto. The coupe body had also appeared, with less powerful engines, in the Hillman Imp Californian announced in January 1967 and the more luxurious Singer Chamois coupe. Production continued to 1976, and around 440,00 units were sold, a far cry from the figures achieved by the Mini, which sold at about 10 times that rate. The car seen here is a late model Imp Super.

HONDA

It is now more than a thirty years since Honda stunned the world with a true Ferrari-beater. Its origins go back all the way to 1984, when Honda commissioned the Italian car designer Pininfarina to design the HP-X (Honda Pininfarina eXperimental), which had a mid-mounted C20A 2.0 L V6 configuration. After Honda committed to the project, management informed the engineers that the new car would have to be as fast as anything coming from Italy and Germany .The HP-X concept car evolved into a prototype called the NS-X, which stood for “New”, “Sportscar” and “eXperimental”. The NS-X prototype and eventual production model were designed by a team led by Chief Designer Ken Okuyama and Executive Chief Engineer Shigeru Uehara, who subsequently were placed in charge of the S2000 project. The original performance target for the NS-X was the Ferrari 328, and later the 348 as the design neared completion. Honda intended the NS-X to meet or exceed the performance of the Ferrari, while offering targeted reliability and a lower price point. For this reason, the 2.0L V6 of the HP-X was abandoned and replaced with a more powerful 3.0L VTEC V6 engine. The bodywork design had been specifically researched by Okuyama and Uehara after studying the 360 degree visibility inside an F-16 fighter jet cockpit. Thematically the F-16 came into play in the exterior design as well as establishing the conceptual goals of the NSX. In the F-16 and other high performance craft such as unlimited hydroplanes, single seat race cars etc. the cockpit is located far forward on the body and in front of the power plant. This “cab-forward” layout was chosen early in the NSX’s design to optimise visibility while the long tail design enhanced high speed directional stability. The NS-X was designed to showcase several Honda automotive technologies, many derived from its F1 motor-sports program. The NS-X was the first production car to feature an all-aluminium monocoque body, incorporating a revolutionary extruded aluminium alloy frame, and suspension. The use of aluminium in the body alone saved nearly 200 kg in weight over the steel equivalent, while the aluminium suspension saved an additional 20 kg; a suspension compliance pivot helped maintain wheel alignment changes at a near zero value. Other notable features included an independent, 4-channel anti-lock brake system; titanium connecting rods in the engine to permit reliable high-rpm operation; an electric power steering system; Honda’s proprietary VTEC variable valve timing system (a first in the US) and, in 1995, the first electronic throttle control fitted to a Honda. With a robust motorsports division, Honda had significant development resources at its disposal and made extensive use of them. Respected Japanese Formula One driver Satoru Nakajima, for example, was involved with Honda in the NS-X’s early on track development at Suzuka race circuit, where he performed many endurance distance duties related to chassis tuning. Brazilian Formula One World Champion Ayrton Senna, for whom Honda had powered all three of his world championship-winning Formula One race cars before his death in 1994, was considered Honda’s main innovator in convincing the company to stiffen the NSX chassis further after initially testing the car at Honda’s Suzuka GP circuit in Japan. Senna further helped refine the original NSX’s suspension tuning and handling spending a whole day test driving prototypes and reporting his findings to Honda engineers after each of the day’s five testing sessions. Senna also tested the NSX at the Nurburgring and other tracks. The suspension development program was far-ranging and took place at the Tochigi Proving Grounds, the Suzuka circuit, the 179-turn Nurburgring Course in Germany, HPCC, and Hondas newest test track in Takasu, Hokkaido. Honda automobile dealer Bobby Rahal (two-time CART PPG Cup and 1986 Indianapolis 500 champion) also participated in the car’s development. The production car made its first public appearances as the NS-X at the Chicago Auto Show in February 1989, and at the Tokyo Motor Show in October 1989 to positive reviews. Honda revised the vehicle’s name from NS-X to NSX before final production and sale. The NSX went on sale in Japan in 1990 at Honda Verno dealership sales channels, supplanting the Honda Prelude as the flagship model. The NSX was marketed under Honda’s flagship Acura luxury brand starting in 1991 in North America and Hong Kong.  It sent shockwaves through the industry, as the car was considerably better than the Ferrari 348 in just about every respect. But that was not the end of the story, of course. While the NSX always was intended to be a world-class sports car, engineers had made some compromises in order to strike a suitable balance between raw performance and daily driveability. For those NSX customers seeking a no-compromise racing experience, Honda decided in 1992 to produce a version of the NSX specifically modified for superior on-track performance at the expense of customary creature comforts. Thus, the NSX Type R (or NSX-R) was born. Honda chose to use its moniker of Type R to designate the NSX-R’s race-oriented design. In 1995, a Targa model was released, the NSX-T, which allowed customers to experience fresh air thanks to two removable targa top panels. The original NSX body design received only minor modifications from Honda in the new millennium when in 2002 the original pop-up headlamps were replaced with fixed xenon HID headlamp units. There was just one of these much admired cars here.

The first Civic to receive the Type R badge was introduced on August 19, 1997, as the EK9. The EK9 shared many characteristics with the Integra Type R DC2/JDM DB8 such as omission of sound deadening and other weight reduction measures, a hand-ported B16B engine, front helical limited-slip differential and a close-ratio transmission. The B16B engine boasted one of the highest power output per litre of all time for a naturally aspirated engine with 185 PS at 8,200 rpm and 160 Nm (118 lb/ft) at 7,500 rpm of torque from 1,595 cc of displacement. For the first time, a strategically seam-welded monocoque chassis was used to improve chassis rigidity. The interior featured red Recaro bucket seats, red door cards, red Type R floor mats, a titanium shift knob, and a Momo leather-wrapped steering wheel. The EK9 was only available for sale in Japan. Performance figures include a 0–60 mph acceleration time of 6.7 seconds and a quarter-mile time of 15.3 seconds. The EK9 could attain a top speed of 225 km/h (140 mph). In 1998, the Civic Type R Motor Sports edition was introduced. It came with steel wheels, the standard grey EK interior, manual windows, no air conditioning and without any other creature comforts. The Type Rx model introduced in 1999 was given a CD player, body-coloured retractable electric door mirrors, power windows, auto air conditioning, keyless entry unlock system, aluminium sports pedals, and a carbon type centre panel. The Type Rx was the final model of the EK9 generation. In 1999, Honda tuning company Spoon Sports designed an N1 racing version of the Type R that had the B16B engine redline increased from 8,400 rpm to 11,000 rpm. Production of the EK9 Civic Type R totalled 16,000 units.

In 2001, Honda introduced the next generation of the Civic Type R as a unique 3-door hatchback to the UK market, which was manufactured in Swindon, England. This European Domestic Market Civic Type R featured a 200 PS 2.0-litre i-VTEC engine (K20A2) and the regular Type R treatment of seam welding, close-ratio 6-speed transmission and upgraded brakes, but did not include some of the other higher-end features, such as the helical LSD and red Recaro race-seats, that were standard on the EK9. However, Honda marketed a JDM (Japanese domestic market) version of the EP3 (which was exclusively manufactured in Swindon, UK and was shipped to Japan), which retained the highly renowned helical LSD similar to that of the EK9 and red Recaro race-seats. Other differences of the JDM model included a more track-oriented chassis/undercarriage settings as compared to the European model as well as a more powerful engine having a power output of 215 PS (designated K20A) had a fully balanced crankshaft assembly with the different intake manifold, exhaust manifold, higher-lift camshafts, higher-compression pistons, chrome-moly flywheel and ECU programming. All of the Japan-spec K20A Type R powertrains were built in Japan and shipped to the Swindon plant to be installed in the Japan-spec Type-R EP3. The JDM EP3 was also available in the traditional Type R Championship White while the EDM was not. The EDM has more relaxed gear ratios and some high rpm torque traded for low rpm torque compared to the JDM. In 2003, the EP3 was updated with many improvements – revised EPS with quicker steering, revised suspension settings, projector headlamps (JDM came equipped with halogens only while the EDM came with an option for HIDs with self-levelling motors), lighter clutch and flywheel assembly, etc. Based on Honda literature, this facelifted (FL) model was targeted at addressing customers’ and critics’ feedback such as understeer on the limit (due to the front MacPherson strut setup), numb steering response and lack of low-end torque. Mugen Motorsports developed an upgraded version of the JDM Civic Type R, with a sport exhaust system and engine tuning, special Mugen Grille, and anti-roll bars for pro racing activities. In 2003 Honda celebrated 30 years of the Civic badge by offering a special edition 30th Anniversary Civic Type R. This special edition features red bucket seats from Recaro, AIR CONDITIONING, privacy glass on the rear windows, a leather MOMO steering wheel, red interior carpet and door cards. The 30th Anniversary models in the UK were available in Nighthawk Black, Satin Silver and Milano Red. Only 300 of these models were produced, 100 in each colour. In 2005 towards the end of the EP3’s production run, Honda introduced the Civic Type R Premier edition which had Recaro Trendline seats (similar to those found in the Anniversary Edition, only in red and black rather than all red), a darker shade of fabric on the rear seat centre sections, a MOMO Steering Wheel, Red Carpet, Door Linings, “Type R” embossed into the front brake calipers and black privacy glass on the rear windows. Air conditioning was an option. They were available in Milano Red, Nighthawk Black, Cosmic Grey and Satin Silver. In 2004 Honda introduced the “C Package” option (¥330,000 JPY) to Japan’s Civic Type R line-up which included an additional colour, Satin Silver Metallic, HID lighting, rear privacy glass, automatic air conditioner and outside air temperature sensor. For the last production year (2005), the EP3 Type R was offered in Vivid Blue Pearl for the European Market. A total of 132 EP3’s, which were all left-hand drive, were produced in Vivid Blue Pearl.

HYUNDAI

Just one example from the N range of hot Hyundai cars was evident here this time, the first of the genre, an i30N.

JAGUAR

The “X300” model was the first XJ produced entirely under Ford ownership, and can be considered an evolution of the outgoing XJ40 generation. Like all previous XJ generations, it featured the Jaguar independent rear suspension arrangement. The design of the X300 placed emphasis on improved build quality, improved reliability, and a return to traditional Jaguar styling elements. At the car’s launch in October 1994 at the Paris Motor Show, Jaguar marketing material made use of the phrase “New Series XJ” to describe the X300 models. The X300 series represented the result of a £200 million facilities renewal program by Ford. which included the introduction of state-of-the-art automated body welding robots manufactured by Nissan. Aesthetically, the X300 received several updates in the design refresh led by Geoff Lawson in 1991. The mostly flat bonnet of the XJ40 was replaced with a fluted, curvaceous design that accentuated the four separate round headlamps. Rear wings were reshaped to accommodate the new wrap-around rear light clusters. Also, the separate black-rubber bumper bar of the XJ40 were replaced with a fully integrated body-coloured bumper. The interior of the X300 was similar to that found in the XJ40, with some revisions. The seats were updated to have a more rounded profile, wood trim was updated with bevelled edges, and the steering wheel was redesigned. Jaguar’s V12 engine and AJ6 inline-six (AJ16) engine were both available in various X300 models, although they received significant updates. Both engines were fitted with distributorless electronic engine management systems. The Jaguar X308 first appeared in 1997 and was produced until 2003. It was an evolution of the outgoing X300 platform, and the exterior styling is nearly identical between the two generations, though there are quite a few detailed differences if you know what to look for. The major change was the under the bonnet. Having discontinued production of both the AJ16 inline-six and V12 engines, Jaguar offered only its newly designed V8 engine (named the AJ-V8.) It was available in either 3.2 or 4.0 litre forms, although certain markets, such as the United States, only received cars powered by the 4.0 litre version. The 4.0 litre version was also supercharged in certain models. Equipment levels were notably more generous than had previously been the case.

LAMBORGHINI

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.

LOTUS

Sole Lotus here was an example of what for the last few months, until the all-electric Eletre came on stream had been the only model being produced, the Emira sportscar.

MAZDA

The Eunos Cosmo (loosely based on the 1985 MX-03 concept car) started production in 1990 on the new JC platform. The Eunos Cosmo was the top-line touring flagship of the Eunos luxury channel. It is the only Mazda to use a triple-rotor engine. The car was a 2+2 coupé and was loaded with power amenities and other luxuries. Following the Japanese luxury theme, only an electronically controlled 4-speed automatic transmission was available that could be placed in manual shift mode and would change the gear selection in the dashboard display from PRNDSL for automatic transmission operation and PRND321 for manual transmission use. Two engines were available, and both were equipped with twin sequential turbochargers; the two-rotor 13B-RE and the three-rotor 20B-REW. The triple rotor 20B had 2 litres (1962 cc) of displacement, making it the largest capacity rotary offered for sale by Mazda. It produces 280 PS (276 bhp) and 403 Nm (297 lb/ft) of torque with twin turbochargers sourced from Hitachi. Two trim packages were offered; the S (Sport) which offered a firm suspension consisting of control arms in the front and a multilink rear suspension, with a cloth inserts added to leather interior and a full length centre console accommodating four passengers, or E (Elegant) which offered a softer-tuned suspension and full leather upholstery. The JC series Cosmo set several firsts in automotive history. Its two rotor 13B-RE and three rotor 20B-REW engines were the first Japanese-built, series production twin sequential turbo systems to be offered for sale on a rotary engine car. The internationally known FD series RX-7 didn’t receive the twin turbo 13B-REW engine until early 1992. The Eunos Cosmo was the first production car to have a built-in GPS navigation system, and the first in Japan to use the “Palmnet” serial data communication system for ECU-to-ECAT operation. The fourth generation Cosmo was ahead of its time electronically as well by being offered with Car Communication System, a CRT colour touch-screen controlling climate control, mobile phone, GPS car navigation, NTSC TV, radio and CD player. The instrumentation used a LCD display rendering analog gauges with indicator needles that “floated” and using vivid colours for various functions. The Cosmo was speed limited to 180 km/h (111.8 mph) to suit Japanese regulations, but the 20B-REW version was capable of 255 km/h (158.4 mph) if given a free run. With over 380 N⋅m (280 lb⋅ft) of torque available at just 1,800 rpm, the Cosmo could launch from standstill to freeway speeds quickly; however, this came at the expense of heavy fuel consumption. The JC Cosmo was expensive even by today’s standards, as Mazda still has not matched the sales price of this car some 22 years later for anything else in its range. The availability of power and speed in the Cosmo appears extravagant in its intended market of Japan once it becomes understood that most of the driving environment consists of two-way streets that are usually zoned at 40 km/h (25 mph) or less, as mentioned in the article Speed limits in Japan. The Cosmo was manufactured from February 1990 until September 1995, and gathered a total of 8,875 sales. A split of 60/40 sales between 13B-REW and 20B-REW variants made the triple rotor 20B-REW version a rarer car. Although the Cosmo remained a Japanese market-only vehicle (export had been proposed originally under the Eunos sales channel, and under the stillborn Amati brand in the USA), used Cosmos have found their way to various RHD countries thanks to import regulations for private importers from these countries. The Cosmo appears in Sega GT and in the Gran Turismo and Gran Turismo 2 games, as well as the arcade game series Wangan Midnight: Maximum Tune 1 through 6RR.

MERCEDES-BENZ

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.

Also here were a number of Mercedes and AMG models. This C63 AMG is the one which may camera recorded.

MINI

In 1969, now under the ownership of British Leyland, the Mini was given a facelift by stylist Roy Haynes, who had previously worked for Ford. The restyled version was called the Mini Clubman, and had a squarer frontal look, using the same indicator/sidelight assembly as the Austin Maxi. The Mini Clubman was intended to replace the upmarket Riley and Wolseley versions, and a new model, dubbed the 1275 GT, was slated as the replacement for the 998 cc Mini Cooper, the 1,275 cc Mini Cooper S continuing alongside the 1275 GT until 1971. The Clubman Estate replaced the Countryman and Traveller. The original “round-front” design remained in production alongside the Clubman and 1275 GT. Production of the Clubman and 1275 GT got off to a slow start because the cars incorporated “lots of production changes” including the relocation of tooling from Cowley to the Longbridge plant: so very few cars were handed over to customers before the early months of 1970. Early domestic market Clubmans were still delivered on cross-ply tyres despite the fact that by 1970 radials had become the norm for the car’s mainstream competitors. By 1973 new Minis were, by default, being shipped with radial tyres, though cross-plies could be specified by special order, giving British buyers a price saving of £8. The most significant update after this came in 1976, when the engine was upgraded to the 110cc A Series unit, cloth seat trim was made standard and the wiper functions were moved to a column stalk. The stick on “wood” trim was replaced by painted coachlines at this time. The Clubman models were deleted in 1980, effectively replaced by the Metro, and they are relatively rare these days. The 1275 GT is often incorrectly described as the “Mini Clubman 1275 GT”. The official name was always just the “Mini 1275 GT”, and it was a separate, distinct model from the Clubman (although it shared the same frontal treatment as the Mini Clubman, and was launched at the same time). It had the 1275cc A Series unit and a 4 speed gearbox, as well as larger wheels. It was also deleted in the autumn of 1980. Although moderately popular when new, it is now seen as something of a poor substitute for the Cooper models, and the survival rate is pretty low, so you don’t see them that often.

MITSUBISHI

This is a Lancer Evo VI, of the type which was produced between January 1999 and February 2001. Based on the Lancer saloon, the Evo kept pace with changes to that model, so the Evo IV, seen in 1996 had been a new model compared to the first three Evo generations. Evo IV, V and VI were all broadly similar with detailed changes coming with each new iteration. The Evolution VI’s changes mainly focused on cooling and engine durability. It received a larger intercooler, larger oil cooler, and new pistons, along with a titanium-aluminide turbine wheel for the RS model, which was a first in a production car. The Evolution VI received new bodywork yet again, with the most easily noticeable change being within the front bumper where the huge fog lights were reduced in size and moved to the corners for better airflow. A new model was added to the GSR and RS lineup; known as the RS2, it was an RS with a few of the GSR’s options. Another limited-edition RS was known as the RS Sprint, an RS tuned by Ralliart in the UK to be lighter and more powerful with 330 hp. Yet another special edition Evolution VI was released in December 1999: the Tommi Mäkinen Edition, named after Finnish rally driver Tommi Mäkinen who had won Mitsubishi four WRC drivers championships. It featured a different front bumper, Red/Black Recaro seats (with embossed T. Mäkinen logo), 17″ Enkei white wheels, a leather Momo steering wheel and shift knob, a titanium turbine that spooled up more quickly, front upper strut brace, lowered ride height (with tarmac stages in mind), and a quicker steering ratio. Amongst other colours, the Evo VI came in either red (Tommi Mäkinen Edition only), white, blue, black or silver with optional special decals, replicating Tommi Mäkinen’s rally car’s colour scheme. This car is also sometimes referred to as an Evolution 6½, Evolution 6.5, or TME for short. There were two “standard” models. The  RS – “rally sport” had a close-ratio 5-speed, minimal interior, rally suspension, Rear 1.5 Way LSD as opposed to AYC, (Shortened close-ratio 5-speed transmission, Optional Enkei Wheels, Optional Recaro Seats, Optional Air Conditioner, Optional Brembo brakes, Optional power windows). The GSR came with a 5-speed, gauge pack, AYC (Active Yaw Control), Anti-Lock Braking System, Recaro front bucket and rear seat, auto air-conditioner, double-din audio, power windows, Brembo brakes. The Tommi Mäkinen Edition Models also came in RS and GSR guise. The RS was the same as the standard RS with close-ratio 5-speed, lowered ride height, Tommi Mäkinen Edition front bumper, and titanium turbine (same option with standard RS) and the GSR was the same as the standard GSR with lowered ride height, Tommi Mäkinen Edition front bumper, Red/Black Recaro seats (with embossed T. Mäkinen logo), 17″ Enkei white wheels and titanium turbine. These cars were fearsomely expensive to run, and as such, you don’t see them very often any more.

NISSAN

The original Micra (chassis name K10) was introduced onto the Japanese market in October 1982 as a challenger to the Honda City, Daihatsu Charade, Suzuki Cultus, and Toyota Starlet. It was intended to replace the Nissan Cherry as the company’s competitor in the supermini sector, as the Cherry model sold in Europe had progressively become larger with each successive generation. In Japan, it was exclusive to Nissan Cherry store locations, as the Japanese market Cherry was renamed March, benefiting from engineering contributions from Nissan’s 1966 acquisition of the Prince Motor Company, who originally developed the outgoing Cherry. The Micra had particularly low fuel consumption made possible by a specially developed engine only used in the Micra, an uncommonly high gearing, and a particularly low weight: only 630 kg (1,389 lb) in early European trim. The low weight target necessitated a minimum of insulation, meaning that early Micras were quite loud. Japanese owners benefitted from the engine below 1000cc when it came time to pay the annual road tax obligation. The body style was originally designed for Fiat as a replacement for the Fiat 127, but Fiat then adopted the Giugiaro-styled Uno instead. It was introduced in the European market in June 1983, and in Canada in 1984 for the 1985 model year (replacing the slightly larger Nissan Pulsar hatchbacks). Because the Micra was launched during Nissan’s rebranding effort to systematically phase out the Datsun name, a small “Datsun” (ダットサン, Dattosan) appeared on the tailgate for the first two years, and in some European markets, the car was known as the “Datsun-Nissan Micra”. The Datsun badges had disappeared completely by the end of 1984. The Micra was initially available with an extremely refined all-aluminium MA10S SOHC engine. European market cars developed 50 PS (49 hp) or 55 PS (54 hp) in the high compression version coupled with the five-speed option. It was also available with either automatic (called “Nissanmatic”), four-speed or five-speed gearbox. Both the automatic and five-speed manual gearboxes were unusual in a supermini at this time. The Nissanmatic model originally had a 60 PS (59 bhp) version of the 1-liter engine. It was one of several important small cars to be launched onto the European market during 1983. Also launched that year were the Fiat Uno, Peugeot 205, Vauxhall Nova (a Britain-only model which had been launched across Europe the previous year as the Opel Corsa) and the second generation of the Ford Fiesta. It sold well in Britain, being launched there in June 1983 and peaking at more than 50,000 sales for the year in 1989, and was one of the most popular imported cars of its era. The model was revised in June 1985, identifiable by a restyled tailgate and larger rear lamp clusters. The Japanese market saw the debut of the first Micra Turbo/MA10ET, where Nissan grafted a turbocharger to the small 1.0 L engine. This version was never sold in Europe, where the only engines ever available were the 1.0 and 1.2 units. The 1.2, with the larger MA12 1.2 L engine with an electronically controlled carburettor with 57 PS (56 hp), arrived in late 1987. A non-catalyzed version produced 60 PS. Another facelift came in March 1989, which consisted of some minor upgrades such as deeper bumpers, a new front grille, minor interior details, and headlight changes. This was also when the five-door hatchback version was introduced in Europe, shortly before Ford launched the third-generation Fiesta which also offered a 5-door model for the first time. The Micra’s chassis spawned a number of variations. The Be-1 (BK10), launched at the Tokyo Motor Show in 1985 (but not sold until 1987), was a limited edition model with a more rounded bodyshape, and only 10,000 were sold. In 1987, the canvas-topped, retro-looking hatchback Pao (パオ) (PK10) was launched (also at the Tokyo Motor Show) and sold to the public in 1989; 51,657 units were sold. The canvas-topped Figaro (フィガロ) (FK10) coupé was unveiled at the same show in 1989, but not released until 1991. Because demand for the Figaro exceeded the 20,000 vehicles built, Nissan sold the car by lottery: winners could place orders for the car. Despite being a JDM-only model, the Figaro is one of the most imported models of the K10 derivatives; its popularity among numerous celebrity owners helped it earn cult status. The K10 ceased production on 21 December 1992, although its replacement had gone into production some months earlier. During its lifetime, the Micra gained a good reputation for reliability and economy. In 1995, it topped the small car class in a reliability survey of four to six-year-old cars undertaken by the German Automobile Association (ADAC), with 7.5 recorded breakdowns per 1,000 vehicles for four-year-old Micras and 11.5 for six-year-old cars: this compared with 8.0 breakdowns per 1,000 cars for four-year-old Volkswagen Polos and 15.3 for six-year-old Polos. (The class loser was the Fiat Uno with 20.7 breakdowns per 1,000 for four-year-old cars and 37.3 for six-year-old Unos. In the longer term, the Micra would also go on to achieve a much higher survival rate than many of its competitors.) In 1988, Nissan launched a limited 10,000-unit run of its homologated (certified) Nissan 1989 Micra Super Turbo (EK10GFR/GAR). Both this and the 1988 Micra R (EK10FR) featured the same highly advanced sequential compound charged (supercharger plus turbocharger) engine in an all-aluminium straight-four 930 cc eight-valve MA09ERT unit that produced 110 PS (108 hp) at 6400 rpm. This car came with either a 3-speed automatic or 5-speed manual gearbox with viscous limited slip differential, as well as options such as air conditioning and electric mirrors. The Micra Super Turbo still holds the crown for the fastest production Micra in Nissan’s history, with factory performance figures of 7.7 seconds to go from 0 to 100 km/h (62 mph) and 15.5 seconds to run a quarter-mile. It has a top speed of 180 km/h (112 mph) (the maximum allowed to Japanese production cars at the time) and continued to be built until December 1991.

Benefiting from Project 901, the C33 Laurel was announced in December 1988. In January 1989, the C33 went on sale and was now only available as a four-door hardtop. The base engine carried over from the previous generation, offering a 1.8-litre four; the available options consisted of a 2-litre six (SOHC, DOHC, or DOHC Turbo) and a 2.8-litre diesel inline-six. Early in 1991, a DOHC 2.5-litre inline-six coupled to a five-speed automatic became available. The C33, in particular, is very popular as a “drift car,” because it has the same floor plan as the Nissan A31 Cefiro and the four-door Nissan Skyline R32. They also have many interchangeable parts, which makes them ideal for modification. The suspension continued to offer MacPherson struts for all wheels but now offered multi-links for the rear suspension from the Skyline, including HICAS II rear-wheel steering. The Toyota competitor was the Cresta while the new Honda Inspire, Mitsubishi Emeraude and the new Mazda luxury sedan ɛ̃fini MS-8 were also alternatives in the increasing crowded segment. The Laurel was repositioned slightly higher as a larger luxury sedan, as its exterior dimensions matched with the more senior Nissan Cedric and Nissan Gloria, which were exclusive to separate Japanese Nissan dealerships (Nissan Store for the Cedric, Nissan Prince Store for the Gloria). The Laurel remained exclusive to Japanese dealership Nissan Store locations. The four-door hardtop front driver and passenger seat belt shoulder strap were connected at the top to the ceiling to enhance rear passenger comfort and convenience. However, the upper portion could be detached, with the shoulder strap emerging from the side door support, resting on the driver’s and passenger’s shoulders. This provided rear passengers with an unobstructed view from the rear seat without the seat belt hanging from the ceiling when the windows were retracted. The upper part would then swing up to the ceiling and could be fastened into place. Trim levels included the Medalist, Medalist Club S, and Gran Limited. The Club S was the only C33 Laurel with the RB25DE option and a front lip spoiler, with other models offering only the RB20, CA18, and RD28 engines. V6 engines were no longer available; instead, the RB20E type (SOHC), RB20DE type (DOHC), RB20DET type (single turbo DOHC) series 6-cylinder 2.0L, CA18i series four-cylinder SOHC1.8L and RD28-series six-cylinder diesel engines were offered. In addition to this, the improved HICAS-II suspension configuration was used. Four-cylinder model (CA18i) series and six-cylinder diesel engine (RD28) in the presence and instruction car specifications. In January 1991, the Laurel was facelifted, and a new RB20E/RB20DE-powered 5-speed AT model crept into the range. In November 1991, 3-series cars RB25DE Catalogue DOHC2.5L added a grade-six-cylinder engine. 2.5L existing and additional models are equipped with previous-generation high-mount side lamps and side-door airbags. The DUET-SS Super Sonic Suspension was also introduced as an extra-cost option on Gran Limited-equipped vehicles. By January 1992, cumulative production achieved 2 million units.

The Nissan 370Z (known as the Fairlady Z Z34 in Japan) is a 2-door, 2-seater sports car (S-segment in Europe) manufactured by Nissan Motor Company. It was announced on October 29, 2006, and was first shown at an event in Los Angeles ahead of the 2008 Greater LA Auto Show, before being officially unveiled at the show itself.  The 370Z is the sixth generation of the Nissan Z-car line, succeeding the 350Z. The 370Z marks the last production car with a naturally aspirated and high-rev V6 coupled to a manual transmission. Almost every piece and component of the 370Z has been redesigned from the previous 350Z. The wheelbase is 4 in (100 mm) shorter at 100.4 in (2,550 mm) and an overall length 2.7 in (69 mm) shorter at 167.1 in (4,240 mm). The overall width has been increased by 1.3 in (33 mm), the rear track by 2.2 in (56 mm), and overall height reduced by 0.3 in (7.6 mm). The smaller exterior dimensions and use of more lightweight materials helped reduce weight. The 370Z features a front aluminium subframe, aluminium-alloy engine cradle, aluminium door panels, an all-aluminium hood, and an aluminium hatch. Front body torsional rigidity is improved by 10 percent with an extensively revised body structure, which includes a new front suspension cradle to reduce front body lateral bending, new rear structural reinforcements, and an underbody “V-bar” to help reduce rear lateral bending. Rear body torsional rigidity is improved by up to 22 percent and rear body vertical bending rigidity is improved by up to 30 percent. Additional enhancements include the use of a carbon fibre composite radiator housing and strengthening of the rear fender and hatch areas. The new structure weighs slightly less than the 350Z. The 370Z uses a front double wishbone suspension, with forged aluminium control arms and steering knuckle. The rear multi-link suspension uses a forged aluminium upper control arm, lower arm and radius rod, the toe control rod is steel and wheel carrier assembly is aluminium. The refreshed 2013 model uses new dampers with the Sport package models. The brakes have been changed from the more expensive Brembo racing brakes to Nissan branded brakes which are manufactured by Akebono. The coefficient of drag is 0.30 and 0.29 with the Sport Package, figures identical to the 350Z. The Japanese model of the 370Z Coupe went on sale in December 1, 2008. The vehicle was unveiled in the 2008 Los Angeles Auto Show, with sales of the North American model beginning at Nissan dealers in early 2009. Standard and optional equipment includes 19-inch RAYS wheels, Bluetooth, Sirius/XM satellite radio, heated electric seats, viscous limited slip differential, Bose sound system with dual subwoofers and 6-CD changer, and automatic climate control. Deliveries of the European model began in April 2009. There was also an open-topped car, the 370Z Roadster which went on sale in late summer 2009 as 2010 model year vehicle. Early models include the 370Z and 370Z Touring, with Sport Package and Navigation packages for the 370Z Touring. European models went on sale as 2010 model year vehicles. Although there were numerous limited edition models that followed, the car changed little over the next several years. The 2020 model year was the final model year for the 370Z. The line was continued by the Nissan Z (RZ34) on a modified version of the same platform

PEUGEOT

The 309 had been conceived as Projet C28 as a replacement for the Talbot Horizon, and as a result its development had been performed by the former Chrysler/Simca wing of PSA. Styling was the responsibility of the former Chrysler-Rootes design studios in Coventry, whilst much of the engineering was done at the Simca site at Poissy in France. The only stipulation from PSA management was that the new car had to use as much existing architecture as possible; hence the use of a stretched Peugeot 205 floorpan and door shells, whilst the Simca engines and transmissions from the Horizon were also carried over. The 309’s design was presaged by the 1982 Peugeot VERA Plus (followed by the VERA Profil in 1985), which were aerodynamic studies developed by Peugeot at the time. The VERA Plus claimed a Cw of only 0.22. Many of the aerodynamic features from the VERA studies found their way into later production Peugeots. Production in France began at the former Simca plant in Poissy in the end of summer 1985, with the first French customers getting their cars in October of that year; but it was decided that RHD models would be built at the Ryton plant near Coventry, which had previously been owned by the Rootes Group and then Chrysler Europe before Peugeot took it over in 1978. The first 309 for the British market rolled off the production line at Ryton in October 1985, and sales began the beginning of 1986, although left-hand drive sales of the Poissy built models began in France in October 1985. The only bodywork available originally was the five-door hatchback. The 309 was not intended to replace Peugeot’s own model, the 305, but the out of step model number (the next small family car after the 305 should have been named “306” which eventually launched in 1993) was intended to distance it from the larger 305 in the marketplace and to reflect the car’s Simca origins. It was also the first Peugeot badged hatchback of this size. With the Talbot brand being phased out on passenger cars, the 309 would succeed the Talbot Horizon. Peugeot had been considering a new Talbot Samba based on the forthcoming Citroën AX supermini, but the success of the Peugeot 205 meant that there was little need for a third supermini within the PSA combine, and so the Samba was discontinued in 1986 with no replacement. The larger Alpine hatchback and Solara saloons were also axed in 1986, a year before Peugeot began production of the similar sized 405, successor to the 305. The 309’s slightly awkward styling (especially when compared with the 205 and 405 of the same era) was due to the decision to reuse the door shells from the 205. The 309 was also originally intended to be differentiated from Peugeot as a Talbot, and was designed “inhouse”. Other Peugeot cars of the time were designed by the famed Italian design house Pininfarina, up until the introduction of the 206 in 1998. The notched hatchback design bears an unintentional similarity to the Dodge Shadow and Plymouth Sundance, which were also developed (entirely separately and cut down from a larger [Chrysler K-Car] platform rather than stretched from a smaller one) to replace the Horizon in North America. The initial engine line up in the United Kingdom market consisted of the chain driven Simca derived 1118 cc (E1A) and 1294 cc (G1A) overhead valve petrol units from the Horizon, and Peugeot provided 1580/1905 cc petrol belt driven overhead camshaft XU units. Spanish-built cars also used the 1442 cc (Y2) and 1592 cc (J2) “Poissy engine”, as seen previously in the Simca 1307 and Solara as well as the Horizon, instead of the 1580 cc OHC. In July 1986 the first diesels arrived, the 1905 cc, 65 PS PSA XUD engined GLD, GRD, followed by the SRD in 1987. Certain export markets also received a 60 PS 1769-cc version of this engine from the beginning. In France, the smaller diesel option only arrived in 1992. With 305 sales dropping considerably, the 309 range was expanded considerably in February 1987, when the three-door bodystyle was added. In line with Peugeot’s naming policy of the time, five-door models generally have equipment levels beginning with the letter G, while three-doors begin with the letter X. Other important new models was the XU 1905 cc-engined high performance GTI version of the 309; this quickly established itself as one of the class leading hot hatch of its time, thanks to very quick acceleration and a better balanced chassis set-up than the already-excellent handling Peugeot 205 GTI. Other new versions in 1987 were the new Automatic (only with five doors) and the XA and XAD two-seater vans which arrived in February. Largely due to its partially British origins, the Peugeot 309 became a popular choice in the United Kingdom, and in 1987, it was joined on the production line by the larger 405. The 309’s successor, the 306, was also built at Ryton, as was the 206, which was the last vehicle in production there when the plant closed in December 2006. The summer of 1989 saw the introduction of the Phase 2 Peugeot 309. It revised the design of the rear, lowering the boot lip, changing the rear lights to a more ‘smoked style’ and making slight alterations to the front radiator grille. Also, an updated interior was required to address severe criticisms levelled at the Phase 1’s, Talbot designed multi piece dashboard which was prone to developing squeaks and rattles. The GTi models received a colour coded one piece rear spoiler as opposed to the Phase 1’s outdated rubber spoiler which, by then, harked back to early 1980s design. Quite importantly a modified gearbox called ‘BE3’ was introduced, a revision of the original ‘BE1’ unit, placing reverse in the “down and to the right” position behind fifth gear, as opposed to the earlier “up and to the left” position next to first gear. Retrospectively, the ‘BE3’ gearboxes are slightly less prone to failure than their earlier counterparts. This was also when Peugeot gradually phased in their, all new, belt driven TU Series overhead camshaft engines, in 1,124 cc and 1,360 cc forms, eventually replacing the trusty Simca units during 1992. The GTi 16 model, featuring the XU9J4 engine from the 405 Mi16, was also introduced at this time; however, these were only sold in mainland Europe. Towards the end of 1992, production of the 309 began to wind down in anticipation for the launch of the new Peugeot 306, returning Peugeot to their normal numbering scheme. In July 1993, the 309 lineup was severely reduced and only the two Vital (petrol or diesel) models remained on sale until December. In total, 1,635,132 Peugeot 309s were built between 1985 and 1993. As of 2018, only 481 Peugeot 309s remained on the roads in the United Kingdom, with another 1,378 registered being kept off the road as SORN.

PORSCHE

Porsche was the declared theme for this event, and there was a very impressive turnout – more even than usual – with a varied array of different models on what is known as “The Strip”.

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.

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.

Replacing the 964, the 993 models were first seen in October 1993, with production starting a few weeks later. Its arrival marked the end of air-cooled 911 models. The 993 was much improved over, and quite different from its predecessor. According to Porsche, every part of the car was designed from the ground up, including the engine and only 20% of its parts were carried over from the previous generation. Porsche refers to the 993 as “a significant advance, not just from a technical, but also a visual perspective.” Porsche’s engineers devised a new light-alloy subframe with coil and wishbone suspension (an all new multi-link system), putting behind the previous lift-off oversteer and making significant progress with the engine and handling, creating a more civilised car overall providing an improved driving experience. The 993 was also the first 911 to receive a six speed transmission. The 993 had several variants, as its predecessors, varying in body style, engines, drivetrains and included equipment. Power was increased by the addition of the VarioRam system, which added additional power, particularly in the mid-ranges, and also resulted in more throttle noise at higher revs; as a consequence, resulted in a 15% increase in power over its predecessor. The external design of the Porsche 993, penned by English designer Tony Hatter, retained the basic body shell architecture of the 964 and other earlier 911 models, but with revised exterior panels, with much more flared wheel arches, a smoother front and rear bumper design, an enlarged retractable rear wing and teardrop mirrors. A major change was the implementation of all alloy multi-link rear suspension attached to an alloy sub frame, a completely new design derived from the 989, a four-door sedan which never went into production. The system later continued in the 993’s successor, the 996, and required the widening of the rear wheel arches, which gave better stability. The new suspension improved handling, making it more direct, more stable, and helping to reduce the tendency to oversteer if the throttle was lifted during hard cornering, a trait of earlier 911s. It also reduced interior noise and improved ride quality. The 993 was the first generation of the 911 to have a 6-speed manual transmission included as standard; its predecessors had 4 or 5-speed transmissions. In virtually every situation, it was possible to keep the engine at its best torque range above 4,500 rpm. The Carrera, Carrera S, Cabriolet and Targa models (rear wheel drive) were available with a “Tiptronic” 4-speed automatic transmission, first introduced in the 964. From the 1995 model year, Porsche offered the Tiptronic S with additional steering wheel mounted controls and refined software for smoother, quicker shifts. Since the 993’s introduction, the Tiptronic is capable of recognising climbs and descents. The Tiptronic equipped cars suffer as compared to the manual transmission equipped cars in both acceleration and also top speed, but the differences are not much notable. Tiptronic cars also suffered a 55 lb (25 kg) increase in weight. The 993’s optional all wheel drive system was refined over that of the 964. Porsche departed from the 964’s setup consisting of three differentials and revised the system based on the layout from its 959 flagship, replacing the centre differential with a viscous coupling unit. In conjunction with the 993’s redesigned suspension, this system improved handling characteristics in inclement weather and still retained the stability offered by all wheel drive without having to suffer as many compromises as the previous all-wheel-drive system. Its simpler layout also reduced weight, though the four wheel drive Carrera 4 weighs 111 lb (50 kg) more than its rear wheel drive counterpart (at 3,131 lb (1,420 kg) vs. 3,020 lb (1,370 kg)). Other improvements over the 964 include a new dual-flow exhaust system, larger brakes with drilled discs, and a revised power steering. A full range of models arrived before the arrival of the 996 generation in 1998.

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.

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

To commemorate the 50th anniversary of the 911’s introduction, Porsche introduced the 911 50th Anniversary Edition at the 2013 Frankfurt Motor Show for the 2014 model year. 1,963 individually-numbered examples were produced. The 50th Anniversary Edition was based on the Carrera S, including the standard 400PS/394 hp 3.8L flat-6 and standard 7-speed manual with the 7-speed PDK transmission an available option. Contrary to the standard Carrera S, however, the 50th Anniversary Edition featured the Porsche Active Suspension Management system and Porsche Torque Vectoring as standard equipment. The optional Powerkit increased the engine’s output to 430PS/424 hp. Cosmetically, the 50th Anniversary Edition featured the wider body of the Carrera 4S, 10 mm lower suspension, special 20″ alloy wheels which reference the iconic Fuchs wheels on classic 911s, chrome trim across the body including the vents on the rear engine cover and window trim, standard SportDesign side mirrors, and a special “911 50” rear badge. Three colours were available: Geyser Grey, Graphite Grey, and black monochrome. On the interior, the 50th Anniversary Edition has vintage-style green instrument dials, white instrument dial needles, retro “houndstooth” seat inserts, and a badge on the trim above the glovebox commemorating the special edition and listing the production number of the vehicle. The 50th Anniversary Edition carried an MSRP of €121,119 including VAT or £92,257, and was only made available to current Porsche owners.

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.

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.

The Targa body style for the 992-generation 911 premiered on the Porsche web-TV channel 9:11 Magazine on 18 May 2020. The models share the all-wheel drive drivetrain of the Carrera 4 with 8-speed PDK transmission and Carrera 4S with PDK or optional seven-speed manual, respectively. Both models are powered by a 3.0-litre twin-turbo flat-six engine, which in the Targa 4 is rated at 380 hp/385 PS and 450 Nm (332 lb/ft) of torque. The power output was increased by 15 bhp as compared to its predecessor. In the Targa 4S, the flat-six is rated at 444 bhp/450 PS, which is 30 bhp more than its predecessor, and a maximum torque of 530 Nm (391 lb/ft), which is 30 Nm (22 lb/ft) more. The Targa 4 is fitted with 330 mm (13.0 in) discs on both axles while the Targa 4S has larger 350 mm (13.8 in) discs on both axles. The Porsche Active Suspension Management (PASM) is part of the standard equipment for the new 911 Targa models. The Porsche Torque Vectoring Plus (PTV Plus), which includes an electronic rear differential lock with fully variable torque distribution, is standard for the Targa 4S and is optional on the Targa 4. In June 2020, Porsche revealed the Targa 4S Heritage Design Edition. The car uses design elements from early Carrera models with for example teardrops on each front fender and the motorsports graphics on the flanks. The car can be ordered with either the seven-speed manual transmission or PDK dual-clutch automatic and the worldwide production is limited to only 992 units.

The 968 was launched in 1992, renamed from the 944, as so little of the outgoing S2 remained unaltered. In addition to the numerous mechanical upgrades, the new model also received significantly evolved styling both inside and out, with a more modern, streamlined look and more standard luxury than on the 944. Production was moved from the Audi plant in Neckarsulm to Porsche’s own factory in Zuffenhausen. The 968 was powered by an updated version of the 944’s straight-four engine, now displacing 3.0 L with 104 mm bore, 88 mm stroke and producing 240 PS. Changes to the 968’s powertrain also included the addition of Porsche’s then-new VarioCam variable valve timing system, newly optimized induction and exhaust systems, a dual-mass flywheel, and updated engine management electronics among other more minor revisions. The 968’s engine was the second-largest four-cylinder ever offered in a production car up to that time. A new 6-speed manual transmission replaced the 944’s old 5-speed, and Porsche’s dual-mode Tiptronic automatic became an available option. Both the VarioCam timing system and Tiptronic transmission were very recent developments for Porsche. The Tiptronic transmission had debuted for the first time ever only 3 years prior to the debut of the 968, on the 1989 Type 964 911. The VarioCam timing system was first introduced on the 968 and would later become a feature of the Type 993 air-cooled six-cylinder engine. The 968’s styling was an evolution on that of the outgoing 944, itself styled evolutionarily from the earlier 924, but elements were borrowed from the more expensive 928 model in an attempt to create a “family resemblance” between models, and the swooping headlamp design, inspired by those of the 959, previewed similar units found later on the Type 993 911. Along with the new styling, the 968 featured numerous small equipment and detail upgrades, including a Fuba roof-mounted antenna, updated single lens tail lamps, “Cup” style 16″ alloy wheels, a wider selection of interior and exterior colours, and a slightly updated “B” pillar and rear quarter window to accommodate adhesive installation to replace the older rubber gasket installation. Because some parts are interchangeable between the 968, 944 and 924, some enthusiasts purchase those parts from Porsche parts warehouses as “upgrades” for their older models. Like the 944, the 968 was sold as both a coupe and a convertible. Much of the 968’s chassis was carried over from the 944 S2, which in itself shared many components with the 944 Turbo. Borrowed components include the Brembo-sourced four-piston brake calipers on all four wheels, aluminium semi-trailing arms and aluminium front A-arms, used in a Macpherson strut arrangement. The steel unibody structure was also very similar to that of the previous models. Porsche maintained that 80% of the car was new. From 1993 through 1995, Porsche offered a lighter-weight “Club Sport” version of the 968 designed for enthusiasts seeking increased track performance. Much of the 968’s luxury-oriented equipment was removed or taken off the options list; less sound deadening material was used, electrical windows were replaced with crank-driven units, upgraded stereo systems, A/C and sunroof were still optional as on the standard Coupe and Convertible models. In addition, Porsche installed manually adjustable lightweight Recaro racing seats rather than the standard power-operated leather buckets (also manufactured by Recaro), a revised suspension system optimised and lowered by 20 mm for possible track use, 17-inch wheels rather than the 16-inch and wider tyres, 225 front and 255 rears rather than 205 and 225 respectively. The four-spoke airbag steering wheel was replaced with a thicker-rimmed three-spoke steering wheel with no airbag, heated washer jets were replaced with non heated, vanity covers in the engine bay were deleted, as was the rear wiper. The Club Sport has no rear seats, unlike the 2+2 Coupé. Club Sports were only available in Grand Prix White, black, Speed yellow, Guards red, Riviera blue or Maritime blue. Seat backs were colour-coded to the body. Club Sport decals were standard in either black, red or white but there was a ‘delete’ option. All Club Sports had black interiors with the 944 S2 door cards. Due to the reduction in the number of electrical items the wiring loom was reduced in complexity which saved weight and also the battery was replaced with a smaller one, again reducing weight. With the no frills approach meaning less weight, as well as the optimising of the suspension, Porsche could focus media attention on the Club Sport variants fast road and track abilities. This helped to slightly bolster the flagging sales figures in the mid-1990s. The Club Sport variant achieved a ‘Performance Car Of The Year’ award in 1993 from Performance Car magazine in the UK. Club Sport models were only officially available in the UK, Europe, Japan & Australia, although “grey market” cars found their way elsewhere. The declared weight of the 968 CS is 1320 kg, ~100 kg lighter than the regular 968. Acceleration from standstill to 100 km/h is 6.3 seconds and a top speed is 260 km/h (160 mph). A UK-only version called “968 Sport”, was offered in 1994 and 1995, and was essentially a Club Sport model (and was produced on the same production line with similar chassis numbers) with electric windows, electric release boot, central locking, cloth comfort seats (different from both the standard and the Club Sport). With the added electrics the larger wiring loom was used. The Sport Variant also got back the two rear seats, again in the cloth material specific to the Sport. At £29,975, the 968 Sport was priced £5,500 lower than the standard 968, but had most of the latter’s desirable “luxuries” and consequently outsold it by a large margin (306 of the 968 Sport models compared to 40 standard 968 coupés). In 1993, Porsche Motorsports at Weissach briefly produced a turbocharged 968 Turbo S, a fairly odd naming choice for Porsche which usually reserves the added “S” moniker for models that have been tuned for more power over a “lesser” counterpart, such as with the 911 Turbo. The 968 Turbo S shared the same body and interior as the Club Sport and visually can be identified by the NACA bonnet hood scoops, adjustable rear wing and deeper front spoiler. Powered by a large 8 valve SOHC cylinder head (944 Turbo S) with 3.0 Litre 944S2 style engine block. Tests conducted in 1993 produced a 0 to 60 mph (97 km/h) of 4.7 seconds and a top speed of 282 km/h (175 mph), performance comparable to the much newer Type 996 911. It generated 305 bhp  at 5600 rpm with a maximum torque of 370 lb·f) at 3000rpm. Only 16 were produced in total and only for sale in mainland Europe. Between 1992 and 1994, Porsche Motorsports Research and Development built and provided a full “Race” version (stripped out 968 Turbo S) for Porsche’s customer race teams. The 968 Turbo RS was available in two variations; a 337 bhp version using the K27 turbocharger from the Turbo S, which was built to the German ADAC GT specification (ballast added to bring the car up to the 1350 kg minimum weight limit), and an international spec version which used a KKK L41 turbocharger producing 350 bhp and was reduced to 1212 kg in weight. Only 4 were ever produced ; 1 Guards Red, 1 Speed Yellow, 1 Black and 1 White. These are the rarest 968s ever produced.

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 centre 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

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 Boxster was introduced in January 2016, and premiered at the 2016 Geneva Motor Show. The 718 Cayman joined the range in April at the Beijing Motor Show. The 718 featured two new horizontally-opposed flat-4 turbocharged engines at 2.0-litre (Boxster/Cayman) and 2.5-litre (Boxster S/Cayman S) displacement with increased torque and horsepower with lower fuel consumption. The S model turbocharger utilizes Variable Turbine Geometry (VTG) technology. The 718 T models were released for the 2020 model year as more sport-oriented versions of the base 718 models. As such, the T features the same 2.0-litre flat-4 engine as the base 718 but adds performance-oriented options such as Porsche’s 20mm drop sport suspension system, the Sport Chrono package with dynamic drivetrain mounts, and a limited-slip differential, GT4 Short Shifter from the GT4, sports exhaust with black tips, along with cosmetic differences including special decals along the lower doors, a smaller-diameter sport steering wheel, door pull straps in place of standard door handles, wheels from the Porsche 992 Carrera S in special Titanium Grey colour, and Titanium Grey rear badging. Also includes Titanium Grey mirror caps, black headlight washers, black interior trim, Sports-Tex Cloth and Leather Sports-plus seats. Later in October 2017, the GTS models were announced with their 2.5-litre engines rated at 365 PS (360 hp). The Boxster could accelerate to 97 km/h (60 mph) from a standstill in 4.1 seconds, and the Cayman in 3.9 seconds. Since 2020, the GTS 4.0 model has been offered for both 718 models. The new model features the 4.0-litre flat-6 from the Cayman GT4 and Boxster Spyder, however de-tuned to 394 hp/400 PS. Both GTS 4.0 models can accelerate to 97 km/h (60 mph) from a standstill in 4.3 seconds. By late 2020, the PDK gearbox was available as an option for 718 GTS 4.0. The acceleration time of 0-60 mph (97 km/h) has been reduced to 3.9 seconds. The exterior of the 718 Boxster and Cayman is very similar to the third generation, more of an evolution than a redesign. The most notable changes are to the rear of the car, which now has a long black-trim bar across the rear connecting the two taillights. The headlights and bumper are also heavily reworked. On the sides, the mirrors have been redesigned, taking hue from the SportDesign mirrors on the GT3. The updated cockpit of the 718 has the 4th generation of the Porsche PCM system, indicated by the display without bezels. This model has multifunction steering wheel controls. The interior remains very similar to the 981 Cayman / Boxster and the 991.2 generation of the Porsche 911. The main change is the new PCM 4.0 infotainment system, which replaces the PCM 3.1. If the optional Sport Chrono package is present, the steering wheel comes with a mode selector switch that includes a selection of Sports and Sports Plus driving modes, resulting in snappier throttle response at the cost of fuel efficiency. Overall, the most prominent design features of the 981 Cayman / Boxster remain, including large air induction ports on the side, and the prominent horizontal aluminium piece used for adding oil and coolant in the trunk. Despite the loss of two cylinders, the 718 Cayman / Boxster was assessed to be mechanically superior to the 981 model with improved acceleration and steering, while the new 4 cylinder engine “cheapens the experience”. The 718 Cayman was declared Motor Trend’s 2nd best Drivers car in 2017, which praised the car’s handling and throttle response. Giving the award, Miguel Cortina noted, “The suspension is just what you want to feel in a car like this—stiff, sporty, rigid. You get a very good sense of what is happening on the road.” By far, the most contentious reaction to the 718 Cayman was the sound of the engine – which received nearly universal criticism by the automotive press. Car and Driver called it a, “raspy, uncouth sound that strikes some drivers as unpleasant and grating.” Top Gear noted that the sound, “fundamentally cheapens the Porsche experience,” and makes the car, “less upmarket, less cultured and sophisticated than it did before.” However, Motor Trend’s Ignition tested the 718 Cayman against the 981 Cayman GT4, and found that the performance gains were so strong the car had the capability to outmanoeuvre the GT4 at a much lower price. They concluded that the tradeoff was probably worth it.

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 acceleration time of 0-60 mph 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.

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.

Getting rare now are examples of the original Cayenne. Thisentered into the global market to a mixed reception, but it proved itself to have excellent performance for an SUV and had comparably good handling as well as powerful engines. The lineup initially consisted of the V8-powered Cayenne S and Cayenne Turbo. Later in the model cycle, VR6 and diesel-powered versions joined the lineup. In the eight model years of the E1 generation, a total of 276,652 units were produced. The name Cayenne was coined by Manfred Gotta. The base model Cayenne is powered by a 3.2-L VR6 engine producing 250 PS. The intake manifold is unique to Porsche, but otherwise the engine is largely the same as the VW engine. Acceleration from 0–100 km/h (0–62 mph) is 9.1 seconds with the manual transmission and 9.7 seconds with the Tiptronic S. The S in the 955 pre-facelift 9PA is powered by a 4.5L V8 engine with a wet-sump lubrication system and variable valve timing. It produces 335 hp and 310 lb/ft (420 Nm) of torque. Acceleration from 0–60 mph (0–97 km/h) takes 6.9 seconds and the top speed is 150 mph (241 km/h). Introduced only for 2006 (as a pre-GTS concept), the Cayenne S Titanium Edition was a one-year exclusive, limited production SUV featuring a lightweight steel body, featuring an aluminium hood (lighter than the one equipped on the Cayenne S), titanium-painted accented body parts, side lower rocker body panels, Sport-Quad Tip Exhaust chrome tailpipes, 19″ titanium painted alloy wheels, bi-xenon headlights, two-tone interior upholstery, Porsche PCM 2.0 w/ trip computer navigation, MP3 audio and Bose cabin surround sound. Under the hood, improvements included sport-tuned suspension, an aerodynamic body package, low-range transfer case, locking differential and a 6-speed automatic Tiptronic S transmission. The Cayenne S Titanium Edition is powered by the same 4.5L V8 engine that powered the Cayenne S – still producing 335 hp and 310 lb/ft (420 Nm) of torque. Acceleration is even quicker than the regular Cayenne S from 0–60 mph (0–97 km/h) at 6.2 seconds and the top speed is 150 mph (241 km/h). In the updated 9PA chassis 957 Cayenne S introduced between 2008 and 2010, it featured a direct fuel injection (DFI) 4.8L V8 engine which produces 380 hp and 500 Nm (370 lb/ft) of torque. It had a 0–100 km/h (62 mph) time of 6.6 seconds with a top speed of 250 km/h. The updated V8 engine featured VarioCam Plus which combine variable valve timing with two-stage valve lift on the inlet side. The E1 Gran-Turismo Sport (GTS) was only offered in the updated 9PA chassis between the year 2008 and 2010. It was the first Porsche of the modern era to feature the GTS abbreviation nameplate in its model designation. Its sporty chassis had been specially developed only for this model variant and it was powered with a performance tuned 405 PS 4.8 L V8. It also featured a lowered sport suspension, sports exhaust system and 21-inch (533 mm) high performance wheels as standard. It was much lighter than a normal Cayenne and had an aerodynamic wide body kit standard from factory. The Porsche Cayenne GTS had a 0–100 km/h (62 mph) time of 6.1 seconds with a top speed of 253 km/h. A six-speed manual transmission was also offered in the GTS. The first-generation 9PA Cayenne Turbo had 450 PS and can accelerate from 0–100 km/h (62 mph) in 5.6 seconds. A Turbo S version was built in 2006 to compete with the Mercedes-Benz ML 63 AMG. The Cayenne Turbo and Turbo S include a low-range case, a locking differential, and height-adjustable, off-road suspension. The Turbo S is powered by a twin-turbocharged 4.5 L V8 that produces 521 PS and 720 Nm (530 lb/ft) of torque; Acceleration from 0–60 mph (97 km/h) takes 5.0 seconds and the top speed is 167 mph (269 km/h); It features a six-speed automatic Tiptronic S transmission. In 2008 an updated 9PA Turbo model, featuring a larger direct fuel injection 4.8-L V8 engine, was revealed at the Beijing Auto Show. It produces 500 PS (368 kW; 493 hp) more power, and can accelerate from 0–60 mph (97 km/h) in 4.9 seconds. Also revealed with the new Turbo, was a new 550 hp Turbo S model. Acceleration from 0–60 mph (97 km/h) for that car takes 4.7 seconds and it can be had with optional ceramic composite brakes. The original Cayenne Diesel was only available in the facelift 9PA chassis, powered by a 3.0-L V6 VW TDI engine, since February 2009. The engine is rated at 240 PS and 550 Nm (410 lb/ft) of torque. The car was unveiled at the 2009 Geneva Motor Show. The diesel can accelerate from 0–60 mph (97 km/h) in 8.2 seconds. The Cayenne S Transsyberia was originally a racing vehicle designed for the Transsyberia rally, in which only 285 were built. The street version was later built to commemorate Porsche’s victory in the Transsyberia rally. It is only available in the 9PA chassis with the 405 hp direct-inject 4.8-L V8 from the Cayenne GTS. Sales began in January 2009, with a targeted production run of 600 road vehicles worldwide (285 for North America), but far fewer were actually built (102 for USA, 17 for Canada including 3 which were 6 speed manual). In May 2009, a limited edition version based on the Cayenne GTS was introduced, designed by Porsche Design Studio and included a Porsche Design chronograph Type P’6612. Production was limited to 1000 units worldwide. The second-generation Porsche Cayenne 92A went on sale in April–May 2010 as a 2011 model, with an official debut at the 2010 Geneva Motor Show.

SUBARU

Subaru introduced the “New Age” Impreza, the second generation car, to Japan in August 2000, and it arrived in Europe towards the end of that year. Larger in size compared to the previous iteration, the sedan increased its width by 40 millimetres (1.6 in), while the wagon notably increased by just 5 millimetres (0.2 in)—placing the two variants in different Japanese classification categories. The coupe body style from the first generation did not reappear for the new series, and the off-road appearance package that included contrasting-coloured bumpers did carry over forward. Marketed as a separate model line, this North America-only variant was, as before, badged the Outback Sport. Naturally aspirated flat-four (boxer) engines comprised the 1.5-litre EJ15, the 1.6-litre EJ16, the 2.0-litre EJ20, and the 2.5-litre EJ25. Turbocharged versions of the 2.0- and 2.5-litre engines were offered in the WRX and WRX STI models. STI models featured a more powerful 2.0-litre (2.5-litre outside of the Japanese market) turbocharged engine. WRX models featured a 2.0-litre turbocharged boxer engine until 2005, after which they switched to the 2.5-litre turbocharged engine. As with the first generation, the turbocharged STI variants were available in numerous specifications with a myriad of limited edition variants sold. The bug-eyed styling was not well received, and Subaru had two further attempts at the front end, neither of which was entirely successful, either, but enthusiasts were happy to overlook the gawky looks because the way the car drove. Subaru issued yearly updates to the STI, tweaking cosmetics and equipment levels, and also improving performance and handling. The car was replaced in 2007 by the third generation Impreza, widely regarded as inferior in many ways to this version.

TOYOTA

The MR2 derived from a 1976 Toyota design project with the goal of a car which would be enjoyable to drive, yet still provide good fuel economy – not necessarily a sports car. Design work began in 1979 when Akio Yoshida from Toyota’s testing department started to evaluate alternatives for engine placement and drive method, finalising a mid-transverse engine placement. Toyota called the 1981 prototype SA-X. From its original design, the car evolved into a sports car, and further prototypes were tested both in Japan and in the US. Significant testing was performed on race circuits including Willow Springs, where former Formula One driver Dan Gurney tested the car. All three generations were in compliance with Japanese government regulations concerning exterior dimensions and engine displacement. The MR2 appeared around the same time as the Honda CR-X, the Nissan EXA, the VW Scirocco from Europe, and the Pontiac Fiero and Ford EXP from North America. Toyota debuted its SV-3 concept car in October 1983 at the Tokyo Motor Show, gathering press and audience publicity. The car was scheduled for a Japanese launch in the second quarter of 1984 under the name MR2. Toyota introduced the first-generation MR2 in 1984, designating it the model code “W10”. When fitted with the 1.5-litre 3A engine, it was known as the “AW10”. Likewise, the 1.6-litre 4A version is identified by the “AW11” code. The MR2’s suspension and handling were designed by Toyota with the help of Lotus engineer Roger Becker. Toyota’s cooperation with Lotus during the prototype phase can be seen in the AW11, and it owes much to Lotus’s sports cars of the 1960s and 1970s. Toyota’s active suspension technology, called TEMS, was not installed. With five structural bulkheads, the MR2 was quite heavy for a two-seater of its size. Toyota employed the naturally aspirated 4A-GE 1,587 cc inline-four engine, a DOHC four-valve-per-cylinder motor, borrowed from the E80 series Corolla. This engine was also equipped with Denso electronic port fuel injection and T-VIS variable intake geometry, giving the engine a maximum power output of 112 hp in the US, 128 hp in the UK, 116 or 124 PS (114 or 122 hp) in Europe (with or without catalytic converter), 118 hp in Australia and 130 PS (128 hp) in Japan. Japanese models were later detuned to 120 PS (118 hp). A five-speed manual transmission was standard, with a four-speed automatic available as an option. In 1986 (1988 for the US market), Toyota introduced a supercharged engine for the MR2. Based on the same block and head, the 4A-GZE was equipped with a small Roots-type supercharger and a Denso intercooler. T-VIS was eliminated and the compression ratio was lowered to 8:1. It produced 145 hp at 6,400 rpm and 186 Nm (137 lb/ft) of torque at 4,400 rpm and accelerated the car from 0 to 100 km/h (62 mph) in 6.5 to 7.0 seconds. The supercharger was belt-driven but actuated by an electromagnetic clutch, so that it would not be driven except when needed, increasing fuel economy. Curb weight increased to as much as 2,494 lb (1,131 kg) for supercharged models, due to the weight of the supercharger equipment and a new, stronger transmission. A fuel selector switch was also added in some markets, to allow the car to run on regular unleaded fuel if required to. In addition to the new engine, the MR2 SC was also equipped with stiffer springs, and received special “tear-drop” aluminium wheels. The engine cover had two raised vents (only one of which was functional) that visually distinguished it from the naturally aspirated models. It was also labelled “SUPER CHARGER” on the rear trunk and body mouldings behind both doors. This model was never offered outside of the Japanese and North American markets, although some cars were privately imported to other countries. Toyota made detailed changes to the car every year until replacing it with a second generation model in 1989.

Needing little introduction, perhaps, is this car, a 2nd generation MR2. Toyota proved that the market for small affordable sports cars was far from dead when they launched the first generation MR2 in 1984. As was the trend at the time among Japanese manufacturers, models were replaced on quite a regular 4/5 year cycle, so it was little surprise when a second generation car appeared in 1989. However, this one would go on to be produced for 10 years, The overall design changed little in that time, but there were lots of small details that were refined during that time. The car was generally well received, with its “mini Ferrari” looks proving quite an attraction, as were the willing engines and the entertaining handling. There are not that many nice clean examples left now, though.

The third-generation MR2 was marketed as the Toyota MR-S in Japan, Toyota MR2 Spyder in the US, and the Toyota MR2 Roadster in Europe. Also known as the Midship Runabout-Sports, the newest MR2 took a different approach than its predecessor, most obviously becoming a convertible and receiving the ‘Spyder’ marketing nomenclature. The first prototype of MR-S appeared in 1997 at the Tokyo Motor Show. The MR2 Spyder chief engineer Harunori Shiratori said, “First, we wanted true driver enjoyment, blending good movement, low inertia and light weight. Then, a long wheelbase to achieve high stability and fresh new styling; a mid-engine design to create excellent handling and steering without the weight of the engine up front; a body structure as simple as possible to allow for easy customizing, and low cost to the consumer.” The only engine available for the ZZW30 was the all-aluminium alloy 1ZZ-FED, a 1.8 litre Inline-four engine. Like its predecessors, it used DOHC and 4 valves per cylinder. The intake camshaft timing was adjustable via the VVT-i system, which was introduced earlier on the 1998 MR2 in some markets. Unlike its predecessors, however, the engine was placed onto the car the other way round, with the exhaust manifold towards the rear of the car instead of towards the front. The maximum power of 138 bhp at 6,400 rpm and 126 lb/ft (171 Nm) of torque at 4,400 rpm was quite a drop from the previous generation, but thanks to the lightness of the car it could still move quite quickly, accelerating from 0 to 100 km/h (62 mph) in 6.8 to 8.7 seconds depending on the transmission option, the Sequential Manual being unable to launch and shift as quickly as the clutch operated manual. Curb weight is 996 kg (2,195 lb) for manual transmission models. In addition to the 5-speed manual transmission, a 6-speed manual or 5-speed Sequential Manual Transmission (SMT) was also available starting in 2002. The SMT was a standard feature in Australian market; however, air conditioning was optional. After 2003, a 6-speed SMT was an option. The SMT had no conventional H-pattern shift lever or clutch pedal. The driver could shift gears by tapping the shift lever forward or backward or by pressing steering-wheel mounted buttons. Clutch engagement is automatic, and the car will automatically shift to second and then first gear when stopping. Cruise control was never offered with the manual transmission, but was standard for SMT-equipped cars. The MR2 Spyder featured a heated glass rear window. A hard top was also available from Toyota in Japan and Europe. Production ended in 2007 and there was no direct successor.

The 170-series Crown, launched in September 1999, features shorter front overhang therefore maximizing interior and trunk space. There are two different 170-series 4-door Saloon; the Royal and Athlete. The Majesta, while sharing the same S170 chassis, is a separate vehicle which is larger and longer than the Crown and has distinctive front and rear styling. The four-door Hardtop was discontinued and no left-hand drive versions were produced, restricting exports to right-hand drive markets like Singapore. The 170-series Estate launched in December 1999 was the first new Crown Wagon after the 130-series and continued in production until June 2007. The engine installed is either the 2.0, 2.5 or 3.0 in-line-six. The Athlete V has 2.5-litre 1JZ-GTE turbo and was offered in both sedan and wagon versions, however the Athlete V wagon was only available until 2003, despite Crown Estate production continuing until 2007. The Royal Saloon was also offered with a 3.0-litre 2JZ-FSE mild hybrid from August 2001 to 2003, using a belted alternator starter system. Later non-hybrid models were offered with the direct-injection version of the 2JZ engine. For the updated Athlete versions starting from August 2001, the tail lamps were changed from incandescent to LED lights and the front grill changed to a mesh design. Furthermore, the grey cloth interior was changed to black cloth, with black leather becoming an available option. Optional 17-inch wheels were also offered starting from 2001. An innovation was the electronically controlled (Toyota Electronic Modulated Suspension) air suspension combining nonlinear H-infinity control of damping force and roll-orientation control. The 170-series Crown replaced the aging 130-series in the Indonesian market. A total of 10,545 Athlete V sedans were manufactured, with a further 5,012 Athlete V Estates manufactured.

Not surprisingly, there were a number of examples of the Yaris GR here.

TVR

The Chimaera was originally intended to replace the Griffith but sufficient demand for both of the models led TVR continuing them. In 1994, TVR introduced the Chimaera 500, a high performance derivative of the Chimaera. The BorgWarner T5 manual transmission replaced the Rover LT77 unit on the rest of the range. A new alternator, power steering and a single Vee belt were fitted to improve reliability. The 4.3 litre engine option was replaced by the 4.0 litre High Compression option. The Chimaera was mildly updated in 1996. Updates included a rear bumper shared with the Cerbera, push button doors with the buttons located under the wing mirrors, a boot lid shared with the Cerbera and the replacement of the front mesh grille with a horizontal bar. The GKN differential was also replaced by a BTR unit. A 4.5 litre model was added to the lineup in 1997. It was originally intended to be fitted with the AJP8 V8 engine but due to the engine not being ready on time, a bored version of the Rover V8 was used instead. In 1998, the rear light styling and the number plate mounting angle was updated while the base 4.0 litre model was discontinued. In 2001, the Chimaera was again facelifted and now featured the Griffith’s headlights as well as seats from the Cerbera. The Chimaera was succeeded by the Tamora in 2002.

The Tuscan was launched in 2000, by which time there had been a series of what we think of as the modern era TVRs produced for nearly a decade, the Cerbera, Griffith and Cerbera. The Tuscan did not replace any of them, but was intended to help with the company’s ambitious push further up market to become a sort of Blackpool-built alternative to Ferrari. It did not lack the styling for the task, and unlike the preceding models with their Rover V8 engines, the new car came with TVR’s own engine, a straight six unit of 3.6 litre capacity putting out 360 bhp. The Tuscan was intended to be the grand tourer of the range, perfectly practical for everyday use, though with only two seats, no ABS, no airbags and no traction control, it was a tough sell on wet days in a more safety conscious world, but at least there was a removable targa top roof panel for those days when the sun came out. The car may have lacked the rumble of a V8, but when pushed hard, the sound track from the engine was still pretty special, and the car was faster than the Cerbera, but sadly, the car proved less than reliable, which really started to harm TVR’s reputation, something which would ultimately prove to be its undoing.

VAUXHALL

The first generation Astra GTE had a short production life, as it was launched in the summer of 1983 and barely 12 months later, a replacement for the entire Astra (Kadett D) range appeared. It used the 1800cc version of the Family Two engine, putting out 115 bhp. The white 1800 GTE was the first UK car to be ‘colour-coded’ with body trim that matched the base colour of the car, this included wheel arch extensions, front side and rear lower skirts, mirror covers, bumpers and even the alloy wheels were painted white. The black, silver and red versions of the GTE also had colour-coding but had the more conventional black bumpers and silver painted alloy wheels.

The second generation of the Vectra was introduced at the 1995 Frankfurt Auto Show, replacing the Vauxhall Cavalier in the UK (first generation sold as Vauxhall Cavalier (UK) Opel Vectra (European mainland) in Europe it sold as an Opel and Australia and New Zealand as a Holden. The range consisted of a 5 door Hatch, 4 door Saloon and 5 door Estate introduced in 1996. Petrol and Diesel engines started with a 8 valve 1.6 litre (later updated to 16v), a 2.0 L Family II engine and a 2.5 L V6, Diesel engines were an Isuza 1.7 litre and Ecotec engines of 2 and 2.2 litre. The Irmscher Vectra was a limited production of the i500, Super Touring and GSi by tuning and body specialist Irsmcher who run the Opel arm of the Super Touring assault

VOLKSWAGEN

Making its customary appearance here was “Eeyore”, the name given by owner Beth Schofield to her very late model Type 2 VW. There were a couple of examples of the Type 2 “Bus”, the second generation of VW’s versatile van range, first seen in late 1967. It was built in Germany until 1979. In Mexico, the Volkswagen Kombi and Panel were produced from 1970 to 1994. Models before 1971 are often called the T2a (or “Early Bay”), while models after 1972 are called the T2b (or “Late Bay”). This second-generation Type 2 lost its distinctive split front windshield, and was slightly larger and considerably heavier than its predecessor. Its common nicknames are Breadloaf and Bay-window, or Loaf and Bay for short. At 1.6 litres and 47 bhp DIN, the engine was also slightly larger. The battery and electrical system was upgraded to 12 volts, making it incompatible with electric accessories from the previous generation. The new model also did away with the swing axle rear suspension and transfer boxes previously used to raise ride height. Instead, half-shaft axles fitted with constant velocity joints raised ride height without the wild changes in camber of the Beetle-based swing axle suspension. The updated Bus transaxle is usually sought after by off-road racers using air-cooled Volkswagen components. The T2b was introduced by way of gradual change over three years. The first models featured rounded bumpers incorporating a step for use when the door was open (replaced by indented bumpers without steps on later models), front doors that opened to 90° from the body, no lip on the front guards, unique engine hatches, and crescent air intakes in the D-pillars (later models after the Type 4 engine option was offered, have squared off intakes). The 1971 Type 2 featured a new, 1.6 litre engine with dual intake ports on each cylinder head and was DIN-rated at 50 bhp. An important change came with the introduction of front disc brakes and new roadwheels with brake ventilation holes and flatter hubcaps. Up until 1972, front indicators are set low on the nose rather than high on either side of the fresh air grille – giving rise to their being nicknamed “Low Lights”. 1972’s most prominent change was a bigger engine compartment to fit the larger 1.7- to 2.0-litre engines from the Volkswagen Type 4, and a redesigned rear end which eliminated the removable rear apron and introduced the larger late tail lights. The air inlets were also enlarged to accommodate the increased cooling air needs of the larger engines. In 1971 the 1600cc Type 1 engine as used in the Beetle, was supplemented with the 1700cc Type 4 engine – as it was originally designed for the Type 4 (411 and 412) models. European vans kept the option of upright fan Type 1 1600 engine but the 1700 Type 4 became standard for US spec models. In the Type 2, the Type 4 engine, or “pancake engine”, was an option for the 1972 model year onward. This engine was standard in models destined for the US and Canada. Only with the Type 4 engine did an automatic transmission become available for the first time in the 1973 model year. Both engines were 1.7 L, DIN-rated at 66 bhp with the manual transmission and 62 bhp with the automatic. The Type 4 engine was enlarged to 1.8 L and 67 bhp DIN for the 1974 model year and again to 2.0 L and 70 bhp DIN for the 1976 model year. The two-litre option appeared in South African manufactured models during 1976, originally only in a comparably well-equipped “Executive” model. The 1978 2.0 L now featured hydraulic valve lifters, eliminating the need to periodically adjust the valve clearances as on earlier models. The 1975 and later U.S. model years received Bosch L-Jetronic electronic fuel injection as standard equipment; 1978 was the first year for electronic ignition, utilising a hall effect sensor and digital controller, eliminating maintenance-requiring contact-breaker points. As with all Transporter engines, the focus in development was not on power, but on low-end torque. The Type 4 engines were considerably more robust and durable than the Type 1 engines, particularly in Transporter service. In 1972, exterior revisions included relocated front turn indicators, squared off and set higher in the valance, above the headlights. Also, square-profiled bumpers, which became standard until the end of the T2 in 1979, were introduced in 1973. Crash safety improved with this change because of a compressible structure behind the front bumper. This meant that the T2b was capable of meeting US safety standards for passenger cars of the time, though not required of vans. The “VW” emblem on the front valance became slightly smaller. Later model changes were primarily mechanical. By 1974, the T2 had gained its final shape. Very late in the T2’s design life, during the late 1970s, the first prototypes of Type 2 vans with four-wheel drive (4WD) were built and tested.

Conceived as a replacement for the popular Beetle Cabrio, and at the time unique in the market place, a convertible version of the Golf was presented to Volkswagen’s management by coachbuilder Wilhelm Karmann GmbH as early as 1976. This early prototype lacked the roll-over bar of the later version, and had a flat body line in the rear, where the soft top folded down below the sill level. The production version of the convertible Golf was designated Type 155. In Europe and Canada it was called the Golf Cabriolet, while in the United States it was sold as the Rabbit Convertible until 1985, when it was also renamed “Cabriolet”. The Cabriolet was sold from 1980 to 1993. It had a reinforced body, a transverse roll-over bar, and a high level of trim. From stamping to final assembly the Mk1 Cabriolet was built entirely at the Karmann factory. Volkswagen supplied engines, suspension, and interior trim for Karmann to install. The tops, of vinyl or cloth, were heavily insulated, with a heated glass rear window. The top was raised and lowered manually until 1991, when it became electrically operated. The body of the Cabriolet did not change through the entire production run except for a larger fuel tank. It kept the pre-1980 style of rear lamp clusters. A space saver spare wheel was fitted from the outset, including 1978 pre-production models, unlike the saloon which did not adopt this until 1984. All Cabriolets from 1988 on left the factory fitted with a “Clipper” bodykit that featured smooth body-coloured bumpers, wheel-arch extensions, and side skirts. Prior to the 1984 model year the highest standard specification Cabriolet was the GLI, which was essentially a GTI in all but name. It was only in late 1983 with the introduction of the 1984 model that an officially badged GTI version of the cabriolet finally became available

A heavily redesigned “Type 2” Scirocco (internally designated Typ 53B) went on sale in 1981, although it remained on the A1 platform. The second generation Scirocco, still assembled on behalf of Volkswagen by Karmann of Osnabrück (in the same factory as the first generation Scirocco), was first shown at the 1981 Geneva Motor Show in March that year. Designed by Volkswagen’s own internal design team, the new car featured increased front and rear headroom, increased luggage space and a reduction in the coefficient of drag. One feature of the Type 2 was the location of the rear spoiler midway up the glass on the rear hatch. A mid-cycle update occurred in 1984, which included minor changes over the 1982 model: removal of the outlined “SCIROCCO” script from the rear hatch (below the spoiler), a redesigned air conditioning compressor, and a different brake master cylinder with in-line proportioning valves and a brake light switch mounted to the pedal instead of on the master cylinder. Halfway through the 1984 model year, a new space-saver spare wheel was added, that provided room for a larger fuel tank (with a second “transfer” fuel pump). Leather interior, power windows and mirrors, air conditioning, and a manual sunroof were options for all years. The 1984 model year saw the return of two windshield wipers (vs the large single wiper), absent since the 1976 models. Eleven different engines were offered in the Type 2 Scirocco over the production run, although not all engines were available in all markets. These engines included both carburettor and fuel injection engines. Initially all models had eight-valve engines. A 16-valve head was developed by tuner Oettinger in 1981, with the modification adopted by Volkswagen when they showed a multi-valve Scirocco at the 1983 Frankfurt Motor Show. It went on sale in Germany and a few other markets in July 1985, with a catalysed model arriving in 1986. Displacements ranged from 1.3 litres up to 1.8 litres. Power ranged from 60 PS to 112 PS for the 8 valve engines and either 129 PS or 139 PS for the 16 valve engines. Numerous trim levels existed, depending on the model year and market, and included the L, CL, GL, LS, GLS, GLI, GT, GTI, GTL, GTS, GTX, GT II, Scala, GT 16V and GTX 16V. Special limited edition models including the White Cat (Europe), Tropic (Europe), Storm (UK), Slegato (Canada), and Wolfsburg Edition (USA and Canada) were also produced. These special models typically featured unique interior/exterior colour combinations, special alloy wheels and had special combinations of options such as leather, multi-function trip computer and/or power windows as standard. Scirocco sales continued until 1992 in Germany, the UK, and some other European markets. The Scirocco was briefly joined but effectively replaced by the Corrado in the VW line-up.

As with the Mk2 Golf, Volkswagen did not make a convertible version of the Mk4 Golf. Instead, they facelifted the front bumper, fenders, hood, and headlights of the Mk3 Golf Cabrio to resemble the styling of the Mk4 Golf (colloquially referred to as the Mk3.5). Changes to the rear included a redesigned hatch, which moved the number plate tub to a restyled rear bumper, in addition to a handle and larger VW emblem more closely resembling the rear of a Mk4 Golf. VW incorporated other non-structural parts from the Mk4 as well, such as fender repeaters, grille, side mirror caps, etc. The interior remained largely similar to the Mk3 interior save for a Mk4 style three-spoke leather steering wheel and airbag, a textured dashboard (also known as “dimpled dash” or “shark skin dash”), heavily bolstered front seats with incorporated side airbags, and a chromed finish on several parts, such as the inner door handles, emergency brake button, door strikers, front seat-belt anchors, key lock cylinders, and shifter button in automatic transmission equipped cars. The instrument panel was updated with a relocated hazard light switch and blue and red backlighting, as found in the Mk4. Technical updates include the immobilizer and engine computer from the Mk4 Golf being retrofit to the older Mk3 engine mechanicals.

VW had enjoyed considerable success with the Scirocco, a front wheel drive Hatch that was based on the Golf, and offered a stylish modern alternative to the Ford Capri and Opel Manta. the second generation car did not quite the same favour as the first, but even so there was eager anticipation of what was initially thought would be the third generation car. But as VW looked to push the model further upmarket, they opted for a new name, choosing Corrado for the car, which debuted in 1988. Although the new car’s floorpan was based on that of the Mark 2 Golf/Jetta, there had been a plan that the model would actually replace the Porsche 944. That idea came to nought and the car, built by Karmann, as the Scirocco had been, took its place in the VW range, alongside the Scirocco which remained in production for a further three years. All Corrados were front-wheel drive and featured petrol engines, the car debuting with two engine choices: a 1.8 litre 16-valve inline-four with 136 hp and a troublesome supercharged 1.8 litre eight-valve inline-four, marketed as the G60 and delivering 160 hp. The Corrado G60 was named for the G-Lader with which it was equipped, a scroll supercharger whose interior resembles the letter “G”. Volkswagen introduced two new engines for 1992. The first was a naturally-aspirated 2.0 litre 16-valve 136 bhp inline-four, basically a further development of the 1.8 litre engine; this engine was not made available to the North American market. The second was the 12-valve VR6 engine, which came in two variants: a 2.8 litre 179 bhp model for the US and Canadian markets and a 2.9 litre 187 bhp version for the European market. Upon revising the engine, VW updated the styling with a new front grille and foglamps. With the introduction of the VR6 engine, the G60 engine disappeared from the North American market after 1992 and European market in 1993. The VR6 engine provided a compromise between both V-shaped and straight engines by placing the two cylinder banks at an angle of 15° with a single cylinder head. This design allowed engineers to fit a six-cylinder engine into roughly the same space that was previously occupied by four-cylinder engines, while closely approaching the smoothness of a straight-six design. By the time it was launched, VW had updated the Golf to the Mark 3,and some elements of its A3 platform was introduced on the Corrado with the VR6 announcement, including the suspension components, the rear axle assembly and some parts of the A3’s ‘plus’ type front axle assembly. The subsequent wider front wheel-track of the Corrado VR6 necessitated the fitting of new front wings with wider wheel arches and liners along with a new front bumper assembly. Together with a new raised-style bonnet to accommodate the VR6 engine, these body improvements were carried across the model range. A 2.0 litre eight-valve model with 115 hp was produced in Europe in 1995. A UK-only limited production model, the Corrado Storm, was also sold. Some discreet “Storm” badging, a colour-keyed front grille, an additional Storm badge on the gear gaiter surround (an upgrade from the standard Karmann badge), 15 inch BBS “Solitude” alloy wheels, and standard fitment of some previously optional items (such as the leather heated front seats) were all that differentiated this model from the base Corrado VR6. Only 500 were produced: 250 in Classic Green with a cream leather interior, and 250 in Mystic Blue, a colour unique to the Storm, with a black leather interior. The Storm models are the most desirable of all these days. Production ended in 1995. Although the car was much praised for its handling, and the VR6 engine was sublime, t was costly, Karmann’s build quality was patchy and those who experienced the G60 versions had more than their fair share of reliability issues (A colleague of mine had at least 4 superchargers blow in the first 60,000 miles). All told, 97,521 Corrados were produced.

Perhaps the record attendance at the April 2024 event set the proverbial expectation bar exceedingly high, so the reduced numbers for this event were noticeable, but even so this was a well-attended event, with a lot of interesting cars to see, and I was kept busy all morning wandering out, using the camera and talking to people, so once again, I missed out on breakfast altogether as they had run out by the time I finally went in quest of something to eat. My diary now gets very congested, so it is unlikely I will be able to attend the next few of these popular meets, but they take place on the second Sunday of every month, and they are commended to anyone interested in cars who can make it.