Dynamic Four, Dynamic ECS, Active TCL In line with this development philosophy, Mitsubishi developed its first high performance
four-wheel drive vehicle in 1987, when it equipped the
Galant VR-4 with
"Dynamic Four", which featured a center
differential-type full-time four-wheel drive system (this system incorporated a
viscous coupling unit), a
four wheel steering system, four-wheel
independent suspension, and a four-wheel ABS (the first total integration of these systems in the world that were highly advanced at the time). The 1987 Galant also featured
"Dynamic ECS", a semi-
active electronically controlled air suspension system (a means of actively controlling a vehicle's cornering attitude and dynamic performance) that Mitsubishi developed. Mitsubishi's active ECS enhanced ride comfort and kept body inclination to a minimum under all driving conditions by controlling the grip between the tires and the road surface. The Galant won the 1987–1988
Japan Car of the Year, the country's most prestigious automotive award. The Dynamic-Four system was honored by the Japan Society for the Promotion of Machine Industry (JSPMI). In 1990, Mitsubishi released the
Diamante (Sigma) in Japan and the
Mitsubishi 3000GT, and the limousine
Mitsubishi Debonair in 1992. They featured a new electronically controlled active trace & traction control system (the first integration of these two systems in the world) that Mitsubishi developed. Simply named TCL in 1990, the system has now evolved into Mitsubishi's modern
Active Skid and Traction Control (ASTC) system. Developed to help the driver maintain the intended line through a corner; an onboard
computer monitored several vehicle operating parameters through various sensors. When too much
throttle has been used when taking a curve, engine output and braking are automatically regulated to ensure the proper line through a curve and to provide the proper amount of traction under various road surface conditions. While conventional traction control systems at the time featured only a slip control function, Mitsubishi's newly developed TCL system had a preventive (active) safety function which improved the course tracing performance by automatically adjusting the traction force (called "trace control") thereby restraining the development of excessive lateral acceleration while turning. Although not a ‘proper’ modern stability control system, trace control monitors steering angle, throttle position and individual wheel speeds although there is no yaw input. The TCL system's standard wheel slip control function enables better traction on slippery surfaces or during cornering. In addition to the TCL system's individual effect, it also works together with Diamante's electronic controlled suspension and four-wheel steering that Mitsubishi had equipped to improve total handling and performance. The Diamante won the
Car of the Year Japan award in 1990–1991.
Birth of the AWC system In 1996, Mitsubishi equipped the Lancer Evolution IV with the world's first
Active Yaw Control (AYC) system. The AYC transfers drive
torque between the left and right drive wheels as required. This was achieved by utilising a torque transfer rear differential which is controlled by various sensors and an
electronic control unit (ECU) to enable a difference in torque to go to each of the rear wheels. The result is an improvement in cornering performance and safety compared to most purely mechanical limited slip rear differentials. The eighth generation Galant/Legnum VR-4 model was released for the Japanese market in 1996 that also featured the AYC system, in addition integrated to now fully evolved active stability control (ASC) system. The ASC generates turning force by employing braking force differentials in left and right wheels. The AYC and ASC integrated system maximizes the
adhesion limits of the vehicle's tires. Controlling each wheel
interdependently, AYC and ASC worked together to improve both safety and performance. The eighth generation Galant won the
Car of the Year Japan award in 1996–1997. In 2001, Mitsubishi equipped the Lancer Evolution VII with the AYC system, Mitsubishi's own
Sports ABS and a newly developed
Active Center Differential (ACD), which used an electronically controlled variable
multi-plate clutch. The ACD has a differential limiting capacity three times greater than that of the viscous coupling-type differential used to date. Also, the ACD's ability to tailor slippage for different driving conditions enabled the levels of steering response and traction control not possible with a viscous coupling differential. In addition, a three-way
manual override switch enables the driver to select
tarmac,
gravel or
snow modes to suit his preferences or driving conditions. The ACD also frees the differential on operation of the
hand brake, allowing the driver to make more effective use of side brake turns in
rallies and
gymkhanas. On the Evolution VII, control of the ACD and AYC systems is integrated for the very first time (integrated management of these systems is the core of Mitsubishi's AWC philosophy). In the integrated system, ACD feedback and feedforward information is transmitted to the AYC control system using parameters in such a way that the larger the ACD differential limiting force is, the larger the yaw moment generated by the AYC system. This integrated control operates so that, for example when accelerating out of a corner, the ACD enhances traction and the AYC enhances steering response and cornering performance, improving acceleration and handling more than the ACD and AYC systems would if they were operating independently. By doing so, the Lancer Evolution VII heralded the birth of Mitsubishi's AWC technology. == Current applications ==