PNEUMATICALLY ACTUATED ACTIVE SUSPENSION SYSTEM FOR REDUCING VEHICLE DIVE AND SQUAT
Keywords:
Active suspension, 14 D.O.F. vehicle model, validation, PID, pitch moment rejection.Abstract
This manuscript provides a detailed derivation of a full vehicle model, which may be used to simulate the behavior of a vehicle in longitudinal direction. The dynamics of a 14 degrees of freedom (14- DOF) vehicle model is derived and integrated with an analytical tire dynamics namely Calspan tire model. The full vehicle model is then validated experimentally with an instrumented experimental vehicle based on the driver input from brake or throttle. Several transient handling tests are performed, including sudden acceleration test and sudden braking test at constant speed. Comparisons of the experimental result and model response with sudden braking and throttling imposed motion are made. The results of model validation showed that the trends between simulation results and experimental data are almost similar with acceptable error. An active suspension control system is developed on the validated full vehicle model to reduce unwanted vehicle motions during braking and throttling maneuver. A proportional-integral-derivative (PID) scheme integrated with pitch moment rejection loop is proposed to control the system. In presented scheme the result verify improved performance of the proposed control structure during braking and throttling maneuvers compared to the passive vehicle system. It can also be noted that the additional pitch moment rejection loop is able to further improve the performance of the PID controller for the system. The proposed controller will be used to investigate the benefits of a pneumatically actuated active suspension system for reducing unwanted vehicle motion in longitudinal direction.References
Fenchea, M. 2008. Influence of Car’s Suspension in the Vehicle Comfort and Active Safety. Annals of the University of Oradea, Fascicle of Management and Technology Engineering. Vol. VII (XVII).
Ahmad, F., Hudha, K., Said. M. R. and Rivai. A. 2008a. Development of Pneumatically Actuated Active Stabilizer Bar to Reduce Vehicle Dive. Proceedings of the International Conference Plan Equipment and Reliability. March 27-28. Kuala Lumpur, Malaysia
Ahmad, F., Hudha, K., Said. M. R. and Rivai. A. 2008b. Development of Pneumatically Actuated Active Stabilizer Bar To Reduce Vehicle squat. Proceedings of the 3rd Brunei International Conference on Engineering and Technology 2008. November 2-5. Bandar Sri Begawan, Brunei Darussalam
Bahouth, G. 2005. Real World Crash Evaluation of Vehicle Stability Control (VSC) Technology. 49th Annual Proceedings Association for the Advancement of Automotive Medicine.
Weeks,D. A., Beno, J. H., Guenin, A. M. and Breise, D. A. 2000.
Electromechanical Active Suspension Demonstration for Off Road Vehicles. SAE Technical Paper Series. Vol.01, No.0102.
Md. Sam, Y. and Osman, and Shah, J. H. 2006. Sliding Mode Control of a Hydraulically Actuated Active Suspension. Jurnal Teknologi, Universiti Teknologi Malaysia. Vol.3, No.44, pp.37-48
Gao, B., Darling, J., Tilley, D. G. and Williams, R.A. 2006. Modeling and Simulation of a Semi-active Suspension System. Department of Mechanical Engineering, University of Bath, Bath a.d Engineering Centre, Jaguar and Land Rover, Whitely, Coventry, BA2 7AY, CV3 4LF.
Sampson, D.J.M., Jeppesen, B.P. and Cebon, D. 2000. The Development of an active roll control system for heavy vehicles. In Proceedings of 6th International Symposium on Heavy Vehicle Weights and Dimensions. pp. 375–384.
Hudha, K., Jamaluddin, H. Samin, P. M. and Rahman, R. A. 2003. Semi Active Roll Control Suspension System on a New Modified Half Car Model. SAE Technical Paper Series. Paper No. 2003-01-2274.
Toshio, Y. and Itaru, T. 2005. Active Suspension Control of a One-wheel Car Model Using Single Input Rules Modules Fuzzy Reasoning and a Disturbance Observer. Journal of Zheijiang University SCIENCE. Vol.6A, No. 4, pp. 251-256.
March, C. and Shim, T. 2007. Integrated Control of Suspension and Front Steering to Enhance Vehicle Handling. Proc. IMeche. Journal of Automobile Engineering. vol. 221, No. 152, pp, 377-391.
Mailah, M. and Priyandoko, G. 2007. Simulation of a Suspension System with Adaptive Fuzzy Active Force Control. International Journal of Simulation Modeling. 6 (1). pp. 25-36. ISSN 1726-4529
Wang, F.C. and Smith, M.C. 2002. Active and Passive Suspension Control for Vehicle Dive and Squat. In: Johansson, R. and Rantzer, A., (eds.) Nonlinear and Hybrid Systems in Automotive Control. Springer-Verlag. London, UK. pp. 23-39. ISBN 1852336528
Labaryade, R. and Aubert, D. 2003. A Single Framework for Vehicle Roll, Pitch, Yaw Estimation and Obstacles Detection by Stereovision. Proceedings IEEE on Intelligent Vehicles Symposium. June 9-11. Columbus, USA. pp. 31-36.
Kruczek, A. and Stribrsky, A.2004. A Full-car Model for Active Suspension – Some Practical Aspects’, Proceedings of the IEEE International Conference on Mechatronics. June 3-5. Istanbul Turkey. pp. 41-45.
Toshio, Y. and Atsushi, T. 2004. Pneumatic Active Suspension System for a One-Wheel Car Model Using Fuzzy Reasoning and a Disturbance Observer. Journal of Zheijiang University SCIENCE. Vol. 5, No. 9, pp. 1060-1068.
Campos, J., Davis, L., Lewis, F., Ikanega, S., Scully, S. and Evans, M. 1999. Active suspension system control of ground vehicle heave and pitch motions. Proceedings of the 7th IEEE Mediterranean Control Conference on Control and Automation. June 28-30.
Vaughan, J., Singhose, W. and Sadegh, N. 2003. Use of Active Suspension Control to Counter the Effects of Vehicle Payloads. Proceeding of IEEE
Conference on Control Applications, 2003 Istanbul, (CCA 2003). June 23-25. Istanbul, Turkey. Vol. 1 pp. 285-289
Ikanega, S. and Lewis, F. L., Campos, J. and Davis, L. 2000. Active Suspension Control of Ground Vehicle Based on a Full-Vehicle Model. Proceeding of the American Control Conference on Ground Vehicle Based. Chicago, lune, Illinois, USA. June 28-30
Zhang, Y., Zhao, L., Cong, H. and Wang, B. 2004. Study on Control of Vehicle Attitude and Ride Comfort Based on Full-car Model. Fifth World Congress on Intelligent Control and Automation, 2004. ( WCICA 2004). Vol.4, pp. 3514- 3519.
Donahue, M. D. 2001. Implementation Of An Active Suspension, Preview Controller For Improove Ride Comfort. Master Thesis University of California, Barkeley.
Sampson, D.J.M. and Cebon, D. 2003a. Achievable Roll Stability of Heavy Road Vehicles. Proc. Instn Mech. Engrs, Part : J. Automobile Engineering. 217(4), pp. 269–287.
Sampson.D.J.M and Cebon.D. 2003b. Active Roll Control of Single Unit Heavy Road Vehicles. Vehicle System Dynamics, International Journal of Vehicle Mechanics and Mobility. Vol. 40, Issue. 4. pp. 229–270.
Karnopp, D. 1995. Active and Semi-active Vibration Isolation. Journal of Mechanical Design, ASME. Vol.177, pp. 177-185.
Yoshimura, T., Isari, Y., Li, Q. and Hino, J. 1997a. Active Suspension of Motor Coaches Using Skyhook Damper and Fuzzy Logic Controls. Control Engineering Practice. Vol. 5, No. 2, pp. 175-184.
Yoshimura, T., Nakaminami, K. and Hino, J. 1997b. A Semi-active Suspension with Dynamic Absorbers of Ground Vehicles Using Fuzzy Reasoning. International Journal of Vehicle Design, Vol. 18, No. 1, pp. 19-34.
Yoshimura, T., Hiwa, T., Kurimoto, M. and Hino, J. 2003. Active Suspension of a One-wheel Car Model Using Fuzzy Reasoning and Compensators. International Journal of Vehicle Autonomous Systems, Vol. 1, No. 2, pp. 196-205.
Yoshimura, T. and Watanabe, K. 2003. Active Suspension of a Full Car Model Using Fuzzy Reasoning Based on Single Input Rule Modules with Dynamic Absorbers’, International Journal of Vehicle Design, Vol. 31, No. 1, pp. 22-40.
Yoshimura, T., Kume, A., Kurimoto, M. and Hino, J. 2001. Construction of An Active Suspension System of a Quarter Car Model Using the Concept of Sliding Mode Control. Journal of Sound and Vibration, Vol. 239, No. 2, pp. 187-199
Stilwell, D. J. and Rugh, W. J. 1999. Interpolation of Observer State Feedback Controllers for Gain Scheduling. IEEE Transactions on Automatic Control. Vol. 44, No. 6, pp. 1225-1229.
Lee, C. H., Shin, M. H. and Chung, N. J. 2001. A Design of Gain-Scheduled Control for a Linear Parameter Varying System: An Application to Flight Control. Control Engineering Practice 9, pp. 11-21
Sedaghati, A. 2006. A PI Controller Based on Gain-Scheduling for Synchronous Generator. Turkish Journal of Electrical Engineering and Computer Sciences. Vol.14, No.2.
Fialho, I and. Balas, G. J. 2002. Road Adaptive Active suspension Design
Using Linear Parameter Varying Gain-Scheduling. IEEE Transactions on Control System Technology. Vol. 10, No. 1, pp. 43-51.
Kadir, Z. A., Hudha, K., Nasir, M. Z. M. and Said, M. R. 2008. Assessment of Tire Models for Vehicle Dynamics Analysis. Proceedings of the International Conference on Plant Equipment and Reliability. March 27-28. Kuala Lumpur, Malaysia.
Ahmad, F., Hudha, K. Rivai. A. and Zakaria, M. M. N. 2008c. Modeling And Validation of Vehicle Dynamic Performance in Longitudinal Direction. Submitted to Journal Of Advanced Manufacturing (JAMT).
Szostak, H. T., Allen, W. R. and Rosenthal, T. J. 1988. Analytical Modeling of Driver Response in Crash Avoidance Maneuvering Volume II: An Interactive Model for Driver/Vehicle Simulation. US Department of
Transportation Report NHTSA DOT HS-807-271. April.
Singh, T., Kesavadas, T., Mayne, R., Kim, J. J. and Roy, A. 2002. Design of Hardware/Algorithms for Enhancement of Driver-vehicle Performance in Inclement Weather Conditions Using a Virtual Environment. SAE 2004 Transactions Journal of Passenger Car: Mechanical Systems. Paper No. 2002-01-0322.
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