Abstract
The dynamic stability of a vehicle depends on various maneuvering features, such as traction, braking, and cornering. This study presents nonlinear vehicle models for estimating the stability region and simulating the dynamic behavior of a vehicle. Two types of vehicle models were found by considering the degrees of freedom and linearity. A simple model with nonlinear tire dynamics is useful for determining the stability region, while a complex model (a multi-body dynamic model in MSC.ADAMS) is appropriate for carrying out accurate simulations. Actual data for a mid-sized passenger car were used, and the models were validated by comparison with test results.
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References
Allen, R. W., Szostak, H. T., Rosenthal, T. J. and Klyde, D. H. (1990). Field testing and computer simulation analysis of ground vehicle dynamic stability. SAE Paper No. 900127.
Allen, R. W., Szostak, H. T., Rosenthal, T. J., Klyde, D. H. and Owens, K. J. (1991). Characteristics influencing ground vehicle lateral/directional dynamic stability. SAE Paper No. 910234.
Allen, R. W. and Rosenthal, T. J. (1993). Computer simulation analysis of safety critical maneuvers for assessing ground vehicle dynamic stability. SAE Paper No. 930760.
Ko, Y. E. and Lee, J. M. (2002). Estimation of the stability region of a vehicle in plane motion using a topological approach. Int. J. Vehicle Design 30,3, 181–192.
Gillespie, T. D. (1992). Fundamentals of Vehicle Dynamics. Society of Automotive Engineers. Warrendale. PA.
Milliken, W. F. and Milliken, D. L. (1995). Race Car Vehicle Dynamics. Society of Automotive Engineers. Warrendale. PA.
Riekert, P. and Schunck, T. (1940). Zur fahrmechanik des gummibereiften kraftfahrzeugs. Ingenieur Archiv, 11, 210–224.
Radt, H. S., Jr. and Van Dis, D. J. (1996). Vehicle handling responses using stability derivatives. SAE Paper No. 960483.
Mashadi, B. and Crolla, D. (1996). Vehicle handling analysis using linearisation around non-linear operating conditions. SAE Paper No. 960482.
Zeng, C. C., Bao, J. H., Zhang, J. W. and Li, X. H. (2006). Dynamics of an actively guided track inspection vehicle. Int. J. Automotive Technology 7,7, 777–784.
MSC Software (2005). Running and Configuring MSC. ADAMS.
Song, C. K. (2003). ADAMS for Kinematics and Dynamics. Intervision Press.
Song, C. K. and Cho, B. K. (2007). MSC.ADAMS for Multi-body Dynamics. Kyobo Pub. Co. Seoul. Korea.
Bakker, E., Pacejka, H. and Lidner, L. (1989). A new tire model with an application in vehicle dynamics studies. SAE Trans. J. Passenger Cars, 98, 101–113.
Schuring, D. J., Pelz, W. and Pottinger, M. G. (1993). The BNPS model — An automated implementation of the magic formula concept. SAE Paper No. 931909.
Schuring, D. J., Pelz, W. and Pottinger, M. G. (1997). The paper-tire concept: A way to optimize tire force and moment properties. SAE Paper No. 970557.
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Ko, Y.E., Song, C.K. Vehicle modeling with nonlinear tires for vehicle stability analysis. Int.J Automot. Technol. 11, 339–344 (2010). https://doi.org/10.1007/s12239-010-0042-0
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DOI: https://doi.org/10.1007/s12239-010-0042-0