Yu F, Cao M, Zheng X. Research on the feasibility of vehicle active suspension with energy regeneration. Journal of Vibration and Shock, 2005, 24: 27–30 (in Chinese)

Karnopp D. Power requirements for vehicle suspension systems. Vehicle System Dynamics, 1992, 21(1): 65–71

Yu C, Wang W, Wang Q. Analysis of energy-saving potential of energy regenerative suspension system on hybrid vehicle. Journal of Jilin University (Engineering and Technology Edition), 2009, 39(4): 841–845 (in Chinese)

Liang J, Shao C. Research on an energy-regenerative active suspension for vehicles. Vehicle & Power Technology, 2010, (1): 55–58 (in Chinese)

Mossberg J, Anderson Z, Tucker C, Recovering Energy from Shock Absorber Motion on Heavy Duty Commercial Vehicles. SAE Technical Paper 2012-01-0814, 2012

Matamoros-Sanchez A Z. The use of novel mechanical devices for enhancing the performance of railway vehicles. Dissertation for the Doctoral Degree. Loughborough: Loughborough University, 2013

Zheng P, Wang R, Gao J, Parameter optimization of power regeneration on the hydraulic electric regenerative shock absorber system. Shock and Vibration, 2019, 2019: 5727849

Zuo L, Zhang P S. Energy harvesting, ride comfort, and road handling of regenerative vehicle suspensions. Journal of Vibration and Acoustics, 2013, 135(1): 011002

Zyga L. Energy-harvesting shock absorber that increases fuel efficiency wins R&D 100 award. Available at Science X website on July 14, 2011

Zhang J, Peng Z, Zhang L, A review on energy-regenerative suspension systems for vehicles. In: Proceedings of the World Congress on Engineering. London, 2013, 1889–1892

Zheng P, Wang R, Gao J. A comprehensive review on regenerative shock absorber systems. Journal of Vibration Engineering & Technologies, 2020, 8(1): 225–246

Wendal G R, Stecklein G. A Regenerative Active Suspension System. SAE Technical Paper 910659, 1991

Fodor M G, Redfield R C. The variable linear transmission for regenerative damping in vehicle suspension control. In: Proceedings of American Control Conference. Chicago: IEEE, 1992, 26–30

Jolly M R, Margolis D L. Regenerative systems for vibration control. Journal of Vibration and Acoustics, 1997, 119(2): 208–215

Aoyoma Y, Kawabate K, Hsegawa S, Development of the Full Active Suspension by Nissan. SAE Technical Paper 901747, 1990

Norisugu T. Energy saving of a pneumatic system (2). Energy regenerative control of a pneumatic drive system. Hydraulics & Pneumatics, 1999, 38(4): 1–4

Stansbury J. US Patent, 9270131. 2016-02-23

Karnopp D. Permanent magnet linear motors used as variable mechanical dampers for vehicle suspensions. Vehicle System Dynamics, 1989, 18(4): 187–200

Ryba D. Semi-active damping with an electromagnetic force generator. Vehicle System Dynamics, 1993, 22(2): 79–95

Gupta A, Mulcahy T M, Hull J R. Electromagnetic shock absorbers. In: Proceedings of the 21st International Modal Analysis Conference. Kissimmee, 2003, 181

Zuo L, Scully B, Shestani J, Design and characterization of an electromagnetic energy harvester for vehicle suspensions. Smart Materials and Structures, 2010, 19(4): 045003

Okada Y, Yonemura J, Shibata M. Regenerative control of moving mass type vibration damper. In: Proceedings of the 4th International Conference on Motion and Vibration Control. Zurich, 1998, 85–90

Suda Y, Nakadai S, Nakano K. Study on the self-powered active vibration control. In: Proceedings of the 4th International Conference on Motion and Vibration Control. Zurich, 1998

Cao M, Liu W, Yu F. Development on electromotor actuator for active suspension of vehicle. Chinese Journal of Mechanical Engineering, 2008, 44(11): 224–228

Zheng X, Yu F. Study on the potential benefits of an energy-regenerative active suspension for vehicles. SAE Transactions, 2005, 114: 242–245

Li Z, Zuo L, Luhrs G, et al. Electromagnetic energy-harvesting shock absorbers: Design, modelling, and road tests. IEEE Transactions on Vehicular Technology, 2013, 62(3): 1065–1074

Hayes R J, Beno J H, Weeks D A. Design and Testing of An Active Suspension System for a 2-1/2 Ton Military Truck. SAE Technical Papers 2005-01-1715. 2005

Beno J H, Worthington M T, Mock J R. Suspension Trade Studies for Hybrid Electric Combat Vehicles. SAE Technical Paper 2005-01-0929, 2005

Zhang Y, Zhang X, Zhan M, Study on a novel hydraulic pumping regenerative suspension for vehicles. Journal of the Franklin Institute, 2015, 352(2): 485–499

Fang Z, Guo X, Xu L, Experimental study of damping and energy regeneration characteristics of a hydraulic electromagnetic shock absorber. Advances in Mechanical Engineering, 2013, 5: 943528

Li C, Tse P W. Fabrication and testing of an energy-harvesting hydraulic damper. Smart Materials and Structures, 2013, 22(6): 065024

Li C, Zhu R, Liang M, Integration of shock absorption and energy harvesting using a hydraulic rectifier. Journal of Sound and Vibration, 2014, 333(17): 3904–3916

Wang R, Gu F, Cattley R, Modelling, testing and analysis of a regenerative hydraulic shock absorber system. Energies, 2016, 9(5): 386

Sharma S K, Saini U, Kumar A. Semi-active control to reduce lateral vibration of passenger rail vehicle using disturbance rejection and continuous state damper controllers. Journal of Vibration Engineering & Technologies, 2019, 7(2): 117–129

Sharma S K, Kumar A. Disturbance rejection and force-tracking controller of nonlinear lateral vibrations in passenger rail vehicle using magnetorheological fluid damper. Journal of Intelligent Material Systems and Structures, 2018, 29(2): 279–297

Sharma S K, Kumar A. Ride comfort of a higher speed rail vehicle using a magnetorheological suspension system. Proceedings of the IMechE, 2018, 232(1): 32–48

Sharma S K, Kumar A. Impact of longitudinal train dynamics on train operations: A simulation-based study. Journal of Vibration Engineering & Technologies, 2018, 6(3): 197–203

Sharma S K, Kumar A. Impact of electric locomotive traction of the passenger vehicle Ride quality in longitudinal train dynamics in the context of Indian railways. Mechanics & Industry, 2017, 18(2): 222

Sharma S K. Multibody analysis of longitudinal train dynamics on the passenger ride performance due to brake application. Proceedings of the IMechE, 2019, 233(2): 266–279

World Health Organization. Global status report on road safety: Time for action. Available at World Health Organization website on June 25, 2009

Serco. VTISM Version 2.6.6 User Guide, 2014

VAMPIRE Dynamics. Vehicle Dynamics Version 6.5. Resonate. Available at VAMPIRE website on July 1, 2016

Wang R. Modelling, testing and analysis of a regenerative hydraulic shock absorber system. Dissertation for the Doctoral Degree. Huddersfield: University of Huddersfield, 2016

Wang R, Chen Z, Xu H, Modelling and validation of a regenerative shock absorber system. In: Proceedings of the 20th International Conference on Automation and Computing (ICAC’14). Cranfield: IEEE, 2014, 32–37

Wang R, Crosbee D, Iwnicki S, Power regeneration in the primary suspension of a railway vehicle. In: Proceedings of the First International Conference on Rail Transportation. Chengdu, 2017

Xu L, Guo X X, Liu J. Evaluation of energy-regenerative suspension structure based on fuzzy comprehensive judgment (FCJ). Advanced Materials Research, 2010, 139–141: 2636–2642

BS EN 12299. Railway applications.  Ride comfort for passengers. Measurement and evaluation. 2009

Nadal J. Theory of Locomotive Stability, Part II: Yaw Motion. Annals of Mines, 1896, 232–255

RSSB. Railway Group Standard GM/RT2141: Resistance of railway vehicles to derailment and roll-over. 2009