Summing ANFIS PID Control of Passenger Seat Vibrations in Active Quarter Car Model
In this paper, passenger seat vibration control of an active quarter car model under random road excitations is considered. The designed ANFIS and Summing ANFIS PID controllers are assembled in primary suspension system of quarter car model. Simulation work is performed in time and frequency domain to obtain passenger seat acceleration and displacement responses. Simulation results show that Summing ANFIS PID based controller is highly suitable to suppress the road induced vibrations in quarter car model to achieve desired passenger ride comfort and safety compared to ANFIS and passive system.
[1] Song, X. B., Ahmadian, M., Southward, S., and Miller, L. R. (2005). An adaptive semiactive control algorithm for magnetorheological suspension systems, J. Vib. Acoust. Trans. ASME, 127(5), 493–502.
[2] Devdutt and Aggarwal, M. L. (2014). Fuzzy control of passenger ride performance using MR shock absorber suspension in quarter car model, International Journal of Dynamics and Control, DOI 10.1007/s40435- 014-0128-z.
[3] Gaspar, P., Szaszi, I., and Bokor, J. (2003). Design of robust controller for active vehicle suspension using the mixed µ synthesis, Vehicle System Dynamics, 40(4), 193-228.
[4] Hong, F., and Pang, C. K. (2012). Robust vibration control at critical resonant modes using indirect-driven self-sensing actuation, Mechatronic Systems, ISA Trans., 51, 834–40.
[5] Fard, H.M., and Samadi F. (2015). Active suspension system control using Adaptive Neuro Fuzzy (ANFIS) controller, IJE Transactions C: Aspects, 28(3), 396-401.
[6] Huang, S. J., and Lin W. C. (2003). A neural network sliding controller for active vehicle suspension, Materials Science Forum, 440-441, 119-126.
[7] Rao, M. V. C., and Prahlad, V. (1997). A tunable fuzzy logic controller for vehicle active suspension system, Fuzzy Sets Systems, 85, 11-21.
[8] Kuo, Y., and Li, T. S. (1999). GA-based fuzzy PI/PD controller for automotive active suspension system, IEEE Transactions on Industrial Electronics, 46, 1051–1056.
[9] Sharkawy, A. B. (2005). Fuzzy and adaptive fuzzy control for the automobile’s active suspension system, Vehicle System Dynamics, 43(11), 795-806.
[10] Yildirim, S., and Eski, l. (2009). Vibration analysis of an experimental suspension system using artificial neural networks, Journal of Scientific & Industrial Research, 68, 522-529.
[11] Lin J., and Lian, R. L. (2011). Hybrid Self-Organizing Fuzzy and Radial Basis-Function Neural-Network Controller for Active Suspension Systems, International Journal of Innovative Computing, Information and Control, 7(6), 3359-3378.
[12] Li, H., Liu, H., Gao, H. and Shi, P. (2012). Reliable Fuzzy Control for Active Suspension Systems with Actuator Delay and Fault, IEEE Transactions on Fuzzy Systems, 20(2), 342-357.
[13] Kothandaraman, R. and Ponnusamy, L. (2012). PSO tuned Adaptive Neuro-fuzzy Controller for Vehicle Suspension Systems, Journal of Advances in Information Technology, 3(1), 57-63.
[14] Devdutt and Aggarwal, M. L. (2016). Active Vibration Control of Passenger Seat with HFPIDCR Controlled Suspension Alternatives, International Journal of Mechanical, Aerospace, Industrial, Mechatronic and Manufacturing Engineering, 10(5), 916-23.
[1] Song, X. B., Ahmadian, M., Southward, S., and Miller, L. R. (2005). An adaptive semiactive control algorithm for magnetorheological suspension systems, J. Vib. Acoust. Trans. ASME, 127(5), 493–502.
[2] Devdutt and Aggarwal, M. L. (2014). Fuzzy control of passenger ride performance using MR shock absorber suspension in quarter car model, International Journal of Dynamics and Control, DOI 10.1007/s40435- 014-0128-z.
[3] Gaspar, P., Szaszi, I., and Bokor, J. (2003). Design of robust controller for active vehicle suspension using the mixed µ synthesis, Vehicle System Dynamics, 40(4), 193-228.
[4] Hong, F., and Pang, C. K. (2012). Robust vibration control at critical resonant modes using indirect-driven self-sensing actuation, Mechatronic Systems, ISA Trans., 51, 834–40.
[5] Fard, H.M., and Samadi F. (2015). Active suspension system control using Adaptive Neuro Fuzzy (ANFIS) controller, IJE Transactions C: Aspects, 28(3), 396-401.
[6] Huang, S. J., and Lin W. C. (2003). A neural network sliding controller for active vehicle suspension, Materials Science Forum, 440-441, 119-126.
[7] Rao, M. V. C., and Prahlad, V. (1997). A tunable fuzzy logic controller for vehicle active suspension system, Fuzzy Sets Systems, 85, 11-21.
[8] Kuo, Y., and Li, T. S. (1999). GA-based fuzzy PI/PD controller for automotive active suspension system, IEEE Transactions on Industrial Electronics, 46, 1051–1056.
[9] Sharkawy, A. B. (2005). Fuzzy and adaptive fuzzy control for the automobile’s active suspension system, Vehicle System Dynamics, 43(11), 795-806.
[10] Yildirim, S., and Eski, l. (2009). Vibration analysis of an experimental suspension system using artificial neural networks, Journal of Scientific & Industrial Research, 68, 522-529.
[11] Lin J., and Lian, R. L. (2011). Hybrid Self-Organizing Fuzzy and Radial Basis-Function Neural-Network Controller for Active Suspension Systems, International Journal of Innovative Computing, Information and Control, 7(6), 3359-3378.
[12] Li, H., Liu, H., Gao, H. and Shi, P. (2012). Reliable Fuzzy Control for Active Suspension Systems with Actuator Delay and Fault, IEEE Transactions on Fuzzy Systems, 20(2), 342-357.
[13] Kothandaraman, R. and Ponnusamy, L. (2012). PSO tuned Adaptive Neuro-fuzzy Controller for Vehicle Suspension Systems, Journal of Advances in Information Technology, 3(1), 57-63.
[14] Devdutt and Aggarwal, M. L. (2016). Active Vibration Control of Passenger Seat with HFPIDCR Controlled Suspension Alternatives, International Journal of Mechanical, Aerospace, Industrial, Mechatronic and Manufacturing Engineering, 10(5), 916-23.
@article{"International Journal of Mechanical, Industrial and Aerospace Sciences:75890", author = "Devdutt", title = "Summing ANFIS PID Control of Passenger Seat Vibrations in Active Quarter Car Model", abstract = "In this paper, passenger seat vibration control of an active quarter car model under random road excitations is considered. The designed ANFIS and Summing ANFIS PID controllers are assembled in primary suspension system of quarter car model. Simulation work is performed in time and frequency domain to obtain passenger seat acceleration and displacement responses. Simulation results show that Summing ANFIS PID based controller is highly suitable to suppress the road induced vibrations in quarter car model to achieve desired passenger ride comfort and safety compared to ANFIS and passive system.
", keywords = "Quarter car model, Active suspension system, Summing ANFIS PID controller, Passenger ride comfort.", volume = "11", number = "5", pages = "1129-7", }
