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Shubham, Ramchandra, Nehe, Ashay, Ghogare, & Shubham, et al. (2018). Design, analysis, simulation and validation of automobile suspension system using drive-shaft as a suspension link. SAE International Journal of Passenger Cars - Mechanical Systems, 11(2), 129-138.Search in Google Scholar
Jiang, B., & Fitzgerald, B. (2021). Development of a rotary screw compressor for electric truck air brake and suspension system. SAE International Journal of Commercial Vehicles.Search in Google Scholar
Sun, Y., Zhou, J., Gong, D., You, T., & Chen, J. (2021). Research on multi-pointconnection of under-chassis equipment suspension system in high-speed trains. AIP Advances, 11(12), -.Search in Google Scholar
Florian, C., Frank, K., & Ajish, B. (2018). Design and field testing of a rover with an actively articulated suspension system in a mars analog terrain. Journal of Field Robotics, 35.Search in Google Scholar
Shehata, A. (2019). Application of a preview control with an mr damper model using genetic algorithm in semi-active automobile suspension. SAE Technical Papers, 1-15.Search in Google Scholar
Wang, W., Tian, K., & Zhang, J. (2020). Dynamic modelling and adaptive control of automobile active suspension system. Journal Europeen des Systemes Automatises(2), 53.Search in Google Scholar
Ranganathan, S., Kuppuraj, S., Ganesan, G. V. R., & Nandhagopal, J. (2019). Modeling and analysis of helical and wave spring behavior for automobile suspension. SAE Technical Papers.Search in Google Scholar
Sun, Z., Shi, Y., Wang, N., & Xu, S. (2021). Mechanism and optimization of a novel automobile pneumatic suspension based on dynamic analysis. Electronics.Search in Google Scholar
Yao, J., Wang, M., Li, Z., & Jia, Y. (2021). Research on model predictive control for automobile active tilt based on active suspension. Energies, 14.Search in Google Scholar
Yang, J., Dong, M., Tandon, P., Wisnoe, W., & Bin Abdullah, M. Z. (2018). Research on vibration of automobile suspension design. Matec Web of Conferences, 153, 04008.Search in Google Scholar
Yousif, A., Jawadaubad, M., & Obaid, S. (2020). Solid state technology analyzing of semi-active suspensions system of a magnetorheological fluid damper for an automobile application under various excitations. Solid State Technology.Search in Google Scholar
Wang, Z., Dong, M., Qin, Y., & Gu, L. (2017). Road profile estimation for suspension system based on the minimum model error criterion combining with kalman filter. Journal of Vibroengineering, 19(6).Search in Google Scholar
Shao, S. J., Jing, D., & Ren, C. B. (2020). Multiobjective optimization of nonlinear active suspension system with time-delayed feedback. Mathematical Problems in Engineering.Search in Google Scholar
Chen, X. (2019). Research on application of artificial intelligence model in automobile machinery control system. International Journal of Heavy Vehicle Systems, 1(1), 1.Search in Google Scholar
Wu, Z., & Xu, G. (2020). Modeling and analysis of a hydraulic energy-harvesting shock absorber. Mathematical Problems in Engineering, 2020.Search in Google Scholar
Rahim, A. A. A., Abdullah, S., Singh, S. S. K., & Nuawi, M. Z. (2019). Reliability assessment on automobile suspension system using wavelet analysis. International journal of structural integrity, 10(5), 602-611.Search in Google Scholar
Sun, X., Cai, Y., Yuan, C., Chen, L., & Wang., R. (2017). Hybrid model predictive control of damping multi-mode switching damper for vehicle suspensions. Journal of Vibroengineering.Search in Google Scholar
Ramli, R., Soong, M. F., Mahadi, W. N. L., & Saifizul, A. (2017). Ride improvement of vehicle suspensions with switchable inerter based on force cancellation strategy. Journal of Vibroengineering.Search in Google Scholar
Cong, H. V. (2021). Consideration on lateral vibration of automobiles in quasi-planar model with wheel separation and road deformation taken into account. Journal of Vibroengineering, 23(1), 17.Search in Google Scholar
Yu, M., Evangelou, S. A., & Dini, D. (2024). Advances in active suspension systems for road vehicles. Engineering, 33, 160-177.Search in Google Scholar
Wargula, U., Wieczorek, B., & Kukla, M. (2019). The determination of the rolling resistance coefficient of objects equipped with the wheels and suspension system – results of preliminary tests. MATEC Web of Conferences, 254(3), 01005.Search in Google Scholar