[1] BOILEAU P É,RAKHEJA S. Whole-body vertical biodynamic response characteristics of the seated vehicle driver:Measurement and model development[J]. International Journal of Industrial Ergonomics,1998,22(6):449-472. [2] DESJARDINS S P. The evolution of energy absorption systems for crashworthy helicopter seats[J]. Journal of the American Helicopter Society,2006,51(2):150-163. [3] WU Y C,CHANG H,TSUNG T T. Dynamic characteristics of a recoil system when firing projectiles with mach 4.4 muzzle velocity from a 105 mm cannon[J]. Journal of Testing and Evaluation,2010,39(4):509-513. [4] 张莉洁,常家东,王炅,等. 磁流变冲击后坐控制系统试验研究[J]. 振动与冲击,2014,33(22):115-120. ZHANG Lijie,CHANG Jiadong,WANG Jiong,et al. Experiments on magneto-rheological recoil control system[J]. Journal of Vibration and Shock,2014,33(22):115-120. [5] 潘公宇,杨海,徐腾跃,等. 磁流变液阻尼器试验与建模研究[J]. 振动与冲击,2015,34(6):36-40. PAN Gongyu,YANG Hai,XU Tengyue,et al. Tests and modeling for magneto-rheological (MR) dampers[J]. Journal of Vibration and Shock,2015,34(6):36-40. [6] 胡红生,王炅,钱苏翔,等. 冲击载荷下的磁流变减振器动力学建模与滑模控制[J]. 机械工程学报,2011,47(13):84-91. HU Hongsheng,WANG Jiong,QIAN Suxiang,et al. Dynamic modeling and its sliding controller of MR shock absorber under impact load[J]. Journal of Mechanical Engineering,2011,47(13):84-91. [7] SHOU M,LIAO C,ZHANG H,et al. Modeling and testing of magnetorheological energy absorbers considering inertia effect with non-averaged acceleration under impact conditions[J]. Smart Materials and Structures,2018,27(11):115028. [8] 程明,陈照波,杨树涛,等. 应用磁流变技术的星箭界面半主动隔振研究[J]. 振动工程学报,2017,30(1):86-92. CHENG Ming,CHEN Zhaobo,YANG Shutao,et al. Study of semi-active satellite and rocket system vibration isolation using magnetorheological technology[J]. Journal of Vibration Engineering,2017,30(1):86-92. [9] HIEMENZ G J,CHOI Y T,WERELEY N M. Semi-active control of vertical stroking helicopter crew seat for enhanced crashworthiness[J]. Journal of aircraft,2007,44(3):1031-1034. [10] SINgh H J,WERELEY N M. Optimal control of gun recoil in direct fire using magnetorheological absorbers[J]. Smart materials and Structures,2014,23(5):055009. [11] LI Z,GONG Y,WANG J. Optimal control with fuzzy compensation for a magnetorheological fluid damper employed in a gun recoil system[J]. Journal of Intelligent Material Systems and Structures,2019,30(5):677-688. [12] WERELEY N M,CHOI Y T,SINGH H J. Adaptive energy absorbers for drop-induced shock mitigation[J]. Journal of Intelligent Material Systems and Structures,2011,22(6):515-519. [13] BAI X X,CHEN P,QIAN L J. Principle and validation of modified hysteretic models for magnetorheological dampers[J]. Smart Materials and Structures,2015,24(8):085014. [14] CHEN P,BAI X X,QIAN L J,et al. An approach for hysteresis modeling based on shape function and memory mechanism[J]. IEEE/ASME Transactions on Mechatronics,2018,23(3):1270-1278. [15] BAI X X,CAI F L,CHEN P. Resistor-capacitor (RC) operator-based hysteresis model for magnetorheological (MR) dampers[J]. Mechanical Systems and Signal Processing,2019,117:157-169. |