This article possibly contains original research. (March 2018)
This article needs additional citations for verification. (September 2018)
The mid-engine, rear-wheel-drive format can be considered the original layout of automobiles. A 1901 Autocar was the first gasoline-powered automobile to use a drive shaft and placed the engine under the seat. This pioneering vehicle is now in the collection of the Smithsonian Institution.
Mounting the engine in the middle instead of the front of the vehicle puts more weight over the rear tires, so they have more traction and provide more assistance to the front tires in braking the vehicle, with less chance of rear-wheel lockup and less chance of a skid or spin out. If the mid-engine vehicle is also rear-drive the added weight on the rear tires can also improve acceleration on slippery surfaces, providing much of the benefit of all-wheel-drive without the added weight and expense of all-wheel-drive components. The mid-engine layout makes ABS brakes and traction control systems work better, by providing them more traction to control. The mid-engine layout may make a vehicle safer since an accident can occur if a vehicle cannot stay in its own lane around a curve or is unable to stop quickly enough. Mid-engine design is also a way to provide additional empty crush space in the front of the automobile between the bumper and the windshield, which can then be designed to absorb more of the impact force in a frontal collision in order to minimize penetration into the passenger compartment of the vehicle.
In most automobiles, and in sports cars especially, ideal car handling requires balanced traction between the front and rear wheels when cornering, in order to maximize the possible speed around curves without sliding out. This balance is harder to achieve when the heavy weight of the engine is located far to the front or far to the rear of the vehicle. Some automobile designs strive to balance the fore and aft weight distribution by other means, such as putting the engine in the front and the gearbox and battery in the rear of the vehicle.
Another benefit comes when the heavy mass of the engine is located close to the back of the seats. It makes it easier for the suspension to absorb the force of bumps so the riders feel a smoother ride. But in sports cars, the engine position is once again used to increase performance and the potentially smoother ride is usually more than offset by stiffer shock absorbers.
This layout also allows the motor, gearbox, and differential to be bolted together as a single unit. Together with independent suspension on the driven wheels, this removes the need for the chassis to transfer engine torque reaction.
The largest drawback of mid-engine cars is restricted rear passenger space; consequently, most mid-engine vehicles are two-seat vehicles. The engine in effect pushes the rear passenger seats forward towards the front axle (if the engine is behind the driver). Exceptions typically involve larger vehicles of unusual length or height in which the passengers can share space between the axles with the engine, which can be between them or below them, as in some vans, large trucks, and buses. The mid-engine layout (with a horizontal engine) was common in single-decker buses in the 1950s and 1960s, e.g. the AEC Reliance. The Ferrari Mondial is to date the only successful example of a true mid-engined convertible with seating for 4 and sports car/supercar performance. A version of the Lotus Evora with a removable roof panel is anticipated but no definite date is known.
Like any layout where the engine is not front-mounted and facing the wind, the traditional "engine-behind-the-passengers" layout makes engine cooling more difficult. This has been a problem in some cars, but this issue seems to have been largely solved in newer designs. For example, the Saleen S7 employs large engine-compartment vents on the sides and rear of the bodywork to help dissipate heat from its very high-output engine.
Mid-engined cars are more dangerous than front-engined cars if the driver loses control - although this may be initially harder to provoke due to the superior balance - and the car begins to spin. The moment of inertia about the center of gravity is low due to the concentration of mass between the axles (similar to standing in the middle of a playground roundabout, rather than at the edge) and the spin will occur suddenly, the car will rotate faster and it will be harder to recover from. Conversely, a front-engined car is more likely to break away in a progressive and controllable manner as the tires lose traction.
Super, sport, and race cars frequently have a mid-engined layout, as these vehicles' handling characteristics are more important than other requirements, such as usable space. In dedicated sports cars, a weight distribution of about 50% front and rear is frequently pursued, to optimise the vehicle's driving dynamics – a target that is typically only achievable by placing the engine somewhere between the front and rear axles.
Usually, the term "mid-engine" has been primarily applied to cars having the engine located between the driver and the rear drive axles. This layout is referred to as rear mid-engine, rear-wheel drive, (or RMR) layout. The mechanical layout and packaging of an RMR car are substantially different from that of a front-engine or rear-engine car.
When the engine is in front of the driver, but fully behind the front axle line, the layout is sometimes called a front mid-engine, rear-wheel-drive, or FMR layout instead of the less-specific term front-engine; and can be considered a subset of the latter. In-vehicle layout, FMR is substantially the same as FR, but handling differs as a result of the difference in weight distribution.
Some vehicles could be classified as FR or FMR depending on the factory-installed engine (I4 vs I6). Historically most classical FR cars such as the Ford Models T and A would qualify as an FMR engine car. Additionally, the distinction between FR and FMR is a fluid one, depending on the degree of engine protrusion in front of the front axle line, as manufacturers mount engines as far back in the chassis as possible. Not all manufacturers use the Front-Mid designation.
FMR layout – Front Mid-engine / Rear-wheel drive
These cars are RWD cars with the engine placed between the driver and the front axle.
- Alfa Romeo 8C Competizione
- AC Cobra
- Aston Martin Vantage (2005), (2018), DB9, DB11, DBS V12, DBS Superleggera
- BMW Z1, Z8
- Chevrolet Corvette (second through seventh generations)
- Bill Thomas Cheetah (used only one universal joint between transmission tailshaft housing and differential housing)
- Dodge A100 and Viper
- Ferrari 599 GTB Fiorano, 612 Scaglietti, F12 Berlinetta, 812 Superfast and GTC4Lusso T
- Ford Econoline (first generation)
- Honda S2000
- Jaguar E-Type
- Lexus LFA
- Maserati Quattroporte V, GranTurismo/GranCabrio
- Mazda Bongo (second generation), RX-7, MX-5 and RX-8
- Mercedes-Benz SLR McLaren, SLS AMG and AMG GT
- Morgan +4, 4/4, Aero 8, Plus Four, Plus Six and Plus 8
- Opel GT (original)
- Porsche 924, 944 and 968
- Shelby Daytona
- Toyota Previa (first generation) and 2000GT
- Most pre-World War II front-engine rear-wheel-drive cars
FM4 layout – Front Mid-engine / Four-wheel drive
This layout, similar to the above FMR layout, with the engine between driver and behind the front axle, adds front-wheel drive to become a four-wheel drive. An engineering challenge with this layout is getting the power to the front wheels past the engine - this would normally involve raising the engine to allow a propshaft to pass under the engine, or in the case of the Ferrari FF taking power from both ends of the crankshaft with two separate gearboxes.
- Ferrari FF/GTC4Lusso
- Hummer H1
- Toyota Previa All-Trac variant
- Toyota Van 4WD variant (first generation)
RMR layout – Rear Mid-engine / Rear-wheel drive
These cars use a traditional engine layout between driver and rear drive axle. Typically, they're simply called MR; for mid-rear (engined), or mid-engine, rear-wheel-drive layout cars.
- Alfa Romeo 4C
- Alpine A110 (2017)
- Apollo Intensa Emozione
- Ariel Atom
- Arrinera Hussarya
- Artega GT
- Aston Martin Valhalla and Valkyrie
- Autozam AZ-1
- BMW M1
- Cadillac Cien
- Chevrolet Corvette (C8)
- Consulier GTP
- DC Avanti
- DeTomaso Vallelunga, Mangusta, Pantera, Guara, P72
- Ferrari 308, 328, 348, F355, 360, F430, 458, 488, F8, 296 GTB, Berlinetta Boxer, Mondial, Testarossa, F40, F50, Enzo, FXX, LaFerrari, FXX-K
- Fiat X1/9
- Ford GT and GT40
- Genty Akylone
- Ginetta F400, G60
- Gumpert Apollo
- Hennessey Venom GT, Venom F5
- Honda Beat, NSX (first generation), and S660
- Jaguar XJ13, XJR-15 and XJ220
- Koenigsegg CC8S, CCR, CCX, Agera, Regera, Jesko
- Lamborghini Miura, Countach, Diablo SV, Jalpa, Silhouette
- Lancia Stratos HF, Lancia Montecarlo
- Lotus Europa, Esprit, Elise, Exige, Evora
- Maserati Merak, Bora, MC12, MC20
- Mastretta MXT
- Matra Djet, 530, Bagheera, Murena
- Mazzanti Evantra
- McLaren F1, MP4-12C, 570S, 650S, 720S, P1, GT, Artura, Senna, Speedtail, Elva
- Mercedes-Benz CLK GTR
- MG F
- Mitsubishi i and i-MiEV (Rear Mid-engine transversely-mounted / Rear-wheel drive)
- Mosler MT900
- Nissan R390 GT1
- Opel Speedster
- Pagani Huayra, Zonda
- Peugeot Onyx
- Pontiac Fiero
- Porsche 550, 914, Boxster/Cayman, Carrera GT, Porsche 911 GT1
- Prince R380
- Renault 5 Turbo, Clio V6 Renault Sport
- Rezvani Beast
- Ruf 3400S, 3600S & 3800S
- Ruf CTR3
- Ruf RK Coupe/Spyder
- Rumpler Tropfenwagen
- Saleen S7
- Scuderia Cameron Glickenhaus SCG 003
- SIN R1
- SSC Aero, Tuatara
- Toyota MR2/MR-S
- Vauxhall VX220
- Vector WX-8
- Vencer Sarthe
- Venturi Atlantique
- Volkswagen W12 Nardo & Roadster, XL1
- W Motors Lykan HyperSport, Fenyr SuperSport
- Zenvo ST1, TS1 GT
M4 layout – Rear Mid-engine / Four-wheel drive
These cars use mid-ship, four-wheel-drive, with an engine between the axles.
- Ares Design Project1
- Audi R8, Sport Quattro RS 002
- BMW i8
- Bugatti Veyron, Chiron, Divo, EB110
- Ford RS200
- Ferrari SF90 Stradale
- Honda Acty (4WD versions only), NSX (second generation), Honda Z (1998-2002)
- Italdesign Zerouno
- Jaguar C-X75
- Jeep Forward Control
- Koenigsegg Gemera
- Lancia Delta S4
- Lamborghini Aventador, Cheetah, Diablo VT series, Gallardo, Murcielago, Reventon, Huracán, Sesto Elemento
- Mercedes-AMG One
- MG Metro 6R4
- Nissan MID4
- Panther Solo 2
- Peugeot 205 Turbo 16
- Porsche 918 Spyder
- Volkswagen W12 Syncro
- Volvo L3314, C303
- Unimog UGN/405
MF layout – Mid-engine / Front-wheel drive
These cars are "mid-ship engined" vehicles, but they use front-wheel drive, with the engine in front of the driver. It is still treated as an FF layout, though, due to the engine's placement still being in the front of the car, contrary to the popular belief that the engine is placed in front of the rear axle with power transferred to the front wheels (an RMF layout). In most examples, the engine is longitudinally mounted rather than transversely as is common with FF cars.
- BSA Scout
- Citroën Traction Avant, DS, SM
- Nissan GT-R LM Nismo
- Renault 4, 5, 16
- Saab Sonett mk1
- Acura Vigor 3rd generation,
- Maserati Quattroporte II 1974–1978
- "America on the Move". 2016-11-02.