Sage Journals: Discover world-class research

Abstract

This study evaluates traction control systems (TCSs) composed of either a wheel slip controller or a throttle valve controller, or an integrated controller of both systems. The dynamic characteristics of a vehicle and a TCS are evaluated using a proposed full car model that can simulate the responses of both front-wheel-drive and four-wheel-drive vehicles. A driver model is also modified to control the vehicle during tests on a road with split Coefficients. The results show that the brake TCS provides more acceleration on uniform slippery and split roads, but the yaw rate and the lateral off set are larger than those obtained when an engine TCS is used. When the vehicle is cornering and accelerating with the brake or engine TCS, understeer or oversteer occur, depending on the driving conditions. An integrated TCS prevents most of these problems and improved the stability and controllability of the vehicle. Four-wheel-drive vehicles exhibit better traction control than two-wheel-drive vehicles, but their steerability is reduced.

Keywords

TCS (traction control system)4WD (four-wheel drive)FWD (front-wheel drive)vehicle model yaw rate split road oversteer understeer

Get full access to this article

View all access options for this article.

References

Denton

Automobile Electrical and Electronic Systems, 1st edition, 1995, pp. 243–259 (SAE International, Warrendale, Pennsylvania).

Ray

L. R.

Non linear system and tire force estimation for advanced vehicle control

IEEE Trans. Control Systems Technol., 1995, 3, 1.

Khatun

Bingham

C. M.

Mellor

P. H.

Comparison of control methods for electric vehicle antilock braking/traction control system. SAE paper 2001-01-0596, 2001.

Jaward

Hachem

Cizmic

Leese

Bowernan

Traction control applications in engine control. SAE paper 2000-01-3464, 2000.

Bang

M. S.

Lee

S. H.

Han

C. S.

Machiuca

D. B.

Hedrick

J. K.

Performance enhancement of a sliding mode wheel slip controller by the yaw moment control

Proc. Instn Mech. Engrs, Part D: J. Automobile Engineering, 2001, 215 (D4), 455–468.

Kazemi

Hamedi

Javadi

A new sliding mode controller for four-wheel anti-lock braking system (ABS). SAE paper 2000-01-1639, 2000.

Liang

Chong

K. T.

T. S.

S. Y.

Vehicle longitudinal brake control using variable parameter sliding control

Control Engng Practice, 2003, 11, 403–411.

Cheok

K. C.

Hoogterp

F. B.

Fales

W. K.

Kobayashi

Scaccia

Fuzzy logic approach to traction control design. SAE paper 960957, 1996.

van Zanten

A. T.

Bosch ESP systems: 5 years of experience. SAE paper 2000-01-1633, 2000.

10.

Jawad

Hachem

Cizmic

Traction control applications in engine control. SAE paper 2000-01-3464, 2000.

11.

Haskara

Ï.

Özgüner

Ü.

Winkelman

Wheel slip control for antispin acceleration via dynamic spark advance

Control Engng Practice, 2000, 8, 1135–1148.

12.

Böning

Folke

Franzke

Traction control (ASR) using fuel-injection suppression—a cost effective method of engine-torque control. SAE paper 920641, 1992.

13.

Dugoff

Fancher

P. S.

Segel

An analysis of tire traction properties and their influence on vehicle dynamic performance. SAE paper 700377, 1970.

14.

Smith

D. E.

Starkey

J. M.

Effects of model complexity on the performance of automated vehicle steering controllers; model development, validation and comparison

Veh. System Dynamics, 1995, 24, 163–181.

15.

Song

Boo

Lim

A study on the performances of hydraulic type electric brake system

Trans. Korean Soc. Mech. Engrs A, 2003, 27 (9), 1492–1498.

16.

Hendrick

Sorenson

S. C.

Mean value modeling of spark ignition engines. SAE paper 900616, 1990.

17.

Fons

Muller

Chevalier

Vigild

Hendrick

Sorenson

S. C.

Mean value engine modelling of an SI engine with EGR. SAE paper 1999-01-0909, 1999.

18.

Renski

Identification of driver model parameters

Int. J. Occupational Safety and Ergonomics, 2001, 7, 1.

19.

Suh

M. W.

Kim

T. G.

Yeo

J. W.

Seok

C. S.

Kim

Y. J.

Lee

J. C.

Development of vehicle model for dynamic analysis of ABS vehicle

Trans. KSAE, 1999, 7, 228–241.

20.

Slotine

Applied Nonlinear Control, 1991, 276–310 (Prentice-Hall, Englewood Cliffs, New Jersey).

21.

Holzwarth

May

Analysis of traction control systems augmented by limited slip differentials. SAE paper 940831, 1994.

22.

Wong

J. Y.

Theory of Ground Vehicles, 3rd edition, 2001, pp. 342–350 (John Wiley, New York).

23.

Mohan

S. K.

Williams

R. C.

A survey of 4WD traction control systems and strategies. SAE paper 952644, 1995.

Performance evaluation of traction control systems using a vehicle dynamic model

Abstract

Abstract

Keywords

Get full access to this article

References