2009.09 - 2013.06，东华大学，机械工程及自动化，学士
2013.09 - 2019.12，上海交通大学，机械工程，博士

2020.01 - 2023.06，上海交通大学，博士后（合作导师：杨斌堂 教授）
2021.12 - 2022.12，巴黎理工学院（ENSTA-Institut Polytechnique de Paris），访问学者（合作导师：Ziad Moumni 教授）

智能材料驱动、传感理论与器件
驱动传感一体化技术与超精密加工
振动主动控制方法与装备

期刊论文：
[1] Xie, D., Yang, Y., & Yang, B. (2022). Self-sensing magnetostrictive actuator based on ΔE effect: design, theoretical modeling and experiment. Smart Materials and Structures, 31(5), 055007.
[2] Sun, X., Hu, W., Bai, Z., & Yang, Y. (2022). Experimental investigation on a new sensitive payload platform with simultaneous positioning and vibration suppression capabilities. Journal of Vibration and Control, 1077546321989498.
[3] Yang, Y., & Yang, B. (2021). Equivalent circuit method based on complete magneto-mechanical coupling magnetostriction parameters for fixed magnetoelectric composites. International Journal of Mechanical Sciences, 199: 106411.
[4] Yang, Y., & Yang, B. (2021). Displacement Sensor with Nanometric resolution Based on Magnetoelectric Effect. IEEE Sensors Journal, 21(10): 12084-12091.
[5] 尹露, 安云, 杨斌堂, 杨诣坤, 卢新刚, & 严隽陶. (2021). 大鼠坐骨神经固有频率测定. 中国医学物理学杂志, 38(5):638-642.
[6] Niu, M. , Yang, B. , Yang, Y. , & Meng, G. . (2020). Modelling and parameter design of a 3-dof compliant platform driven by magnetostrictive actuators. Precision Engineering, 66, 255-268.
[7] Sun, X. , Yang, B. , Gao, Y. , & Yang, Y. . (2020). Integrated design, fabrication, and experimental study of a parallel micro-nano positioning-vibration isolation stage. Robotics and Computer-Integrated Manufacturing, 66, 101988.
[8] Liu, L., Yang, Y., & Yang, B. (2020). Non-contact and high-precision displacement measurement based on tunnel magnetoresistance. Measurement Science and Technology, 31(6), 065102.
[9] 卢新刚, 尹露, 安云, 伍丹丹, 杨诣坤, 杨斌堂, & 严隽陶. (2020). 大鼠脑组织固有频率测定. 中国医学物理学杂志, 37(12):1560-1565.
[10] Hu, W., Gao, Y., Sun, X., Yang, Y., & Yang, B. (2019). Semi-active vibration control of a rotating flexible plate using stiffness and damping actively tunable joint. Journal of Vibration and Control, 25(21-22), 2819-2833.
[11] Sun, X., Wang, Z., & Yang, Y. (2019). Design and experimental investigation of a novel compliant positioning stage with low-frequency vibration isolation capability. Sensors and Actuators A: Physical, 295, 439-449.
[12] 牛牧青, 杨斌堂, 杨诣坤, 孟光, & 陈立群. (2019). 磁致伸缩主被动隔振装置中的磁机耦合效应研究. 力学学报, 51(2), 324-332.
[13] 史智君, 严隽陶, 杨斌堂, 杨诣坤, 孔亚敏, 卢新刚, & 伍丹丹. (2019). 坐骨神经损伤后大鼠臀大肌、小腿三头肌固有频率测定的实验研究. 中国医学物理学杂志, 36(6):721-726.
[14] Yang, Y., Niu, M., & Yang, B. (2018). Static nonlinear model of both ends clamped magnetoelectric heterostructures with fully magneto-mechanical coupling. Composite Structures, 201, 625-635.
[15] Hu, W., He, Q., Sun, X., Yang, Y., & Yang, B. (2018). Design of an innovative active hinge for Self-deploying/folding and vibration control of solar panels. Sensors and Actuators A: Physical, 281, 196-208.
[16] Yang, Y., Yang, B., & Niu, M. (2018). Dynamic/static displacement sensor based on magnetoelectric composites. Applied Physics Letters, 113(3), 032903.
[17] Yang, Y., Yang, B., & Niu, M. (2018). Adaptive infinite impulse response system identification using opposition based hybrid coral reefs optimization algorithm. Applied Intelligence, 48(7), 1689-1706.
[18] Yang, Y., Yang, B., & Niu, M. (2018). Adaptive trajectory tracking of magnetostrictive actuator based on preliminary hysteresis compensation and further adaptive filter controller. Nonlinear Dynamics, 92(3), 1109-1118.
[19] Niu, M., Yang, B., Yang, Y., & Meng, G. (2018). Two generalized models for planar compliant mechanisms based on tree structure method. Precision Engineering, 51, 137-144.
[20] 谢宝莹, 杨斌堂, 杨诣坤, 曹逢雨, & 易思成. (2018). 新型电磁振动台低频振动控制研究. 噪声与振动控制, 38(3).
[21] Yang, Y., Yang, B., & Niu, M. (2017). Spline adaptive filter with fractional-order adaptive strategy for nonlinear model identification of magnetostrictive actuator. Nonlinear Dynamics, 90(3), 1647-1659.
[22] Sun, X., Yang, Y., Hu, W., & Yang, B. (2017). Optimal design and experimental performances of an integrated linear actuator with large displacement and high resolution. Microsystem Technologies, 23(10), 5051-5061.
[23] Niu, M., Yang, B., Yang, Y., & Meng, G. (2017). Modeling and optimization of magnetostrictive actuator amplified by compliant mechanism. Smart Materials and Structures, 26(9), 095029.
[24] Yang, Y., Yang, B., & Niu, M. (2017). Parameter identification of Jiles–Atherton model for magnetostrictive actuator using hybrid niching coral reefs optimization algorithm. Sensors and Actuators A: Physical, 261, 184-195.
[25] Niu, M., Yang, B., Yang, Y., & Meng, G. (2017). Dynamic modelling of magnetostrictive actuator with fully coupled magneto-mechanical effects and various eddy-current losses. Sensors and Actuators A: Physical, 258, 163-173.
[26] Yang, B., & Yang, Y. (2016). A new angular velocity sensor with ultrahigh resolution using magnetoelectric effect under the principle of Coriolis force. Sensors and Actuators A: Physical, 238, 234-239.

会议论文：
[1] Xie, D., Zhang, Y., Wu, H., Yang, Y., & Yang, B. (2022). Self-sensing Giant Magnetostrictive Actuator with Real-time Detection of Mechanical Stress. In ACTUATOR 2022; International Conference and Exhibition on New Actuator Systems and Applications (pp. 1-4). VDE.
[2] Yang Y., Wu H., Yang B. (2021). Self-sensing Nanometric Magnetoelectric Actuator Based on Metglas/PZT Composites. In ACTUATOR 2021 International Conference and Exhibition on New Actuator Systems and Applications, February 17-19, Online.
[3] Liu, L., Yang, Y., & Yang, B. (2020). A resonant pressure sensor based on magnetostrictive/piezoelectric magnetoelectric effect. In 5th International Conference on Mechanical, Manufacturing, Modeling and Mechatronics (IC4M 2020), February 27-29, Shenzhen, China.
[4] Yang, Y., Yang, B., & Niu, M. (2018). Hybrid Frequency-dependent Hysteresis Model of Magnetostrictive Actuator. In IOP Conference Series: Materials Science and Engineering (Vol. 378, No. 1, p. 012013). IOP Publishing.
[5] Cao, F., Niu, M., Yang, Y., Xie, B., & Yang, B. (2017). Modeling of the electromagnetic drive torque on the permanent magnet in a novel drive mechanism. In Applied Mechanics and Materials (Vol. 872, pp. 310-315). Trans Tech Publications Ltd.

授权发明专利：
[1] 杨斌堂；杨诣坤. 微流量控制装置及其控制和阀门检测方法. ZL201710336166.4
[2] 杨斌堂；吴浩慜；杨诣坤. 适用于摆转动体角度、角速度复合检测传感器及检测装置. ZL202111487973.9.
[3] 杨斌堂；张啸；杨诣坤；乔凤斌；金弘哲；胡佳成；肖杰.高频小位移非接触式双轴振动台. ZL202110332843.1.
[4] 杨斌堂；张啸；黄兴保；杨诣坤；王卫军；丁立超.着陆缓冲系统落震试验装置及方法. ZL202110291248.8.
[5] 杨斌堂；张啸；杨诣坤；乔凤斌；金弘哲；胡佳成；肖杰.低频大幅值变放大比双轴振动台. ZL202110332848.4.
[6] 杨斌堂；刘鲁楠；杨诣坤.基于非刚性连接的刚性力控制装置. ZL201911348037.2.
[7] 杨斌堂；邓凯；杨诣坤.零件在线检测及数据处理平台以及方法. ZL201910497222.1.
[8] 杨斌堂；刘鲁楠；杨诣坤.基于磁致伸缩材料的自传感驱动器. ZL201811204066.7.
[9] 杨斌堂；牛牧青；杨诣坤；孟光.磁致伸缩驱动主被动一体多自由度精密隔振装置. ZL201510253823.X.
[10] 杨斌堂；杨诣坤.基于科里奥利力效应的微型传感装置及其组合结构. ZL201410784796.4.

软件著作权登记：
[1] 综合性能测试仪振动系统测试平台辅助软件，原始取得，2021SR0669799

Applied Thermal Engineering、Journal of Physics D: Applied Physics、Sensors、Smart Materials and Structures、Physica Scripta等期刊审稿人
中国仪器仪表学会 会员
Actuators特刊Recent Developments in Precision Actuation Technologies客座编辑

2020.11 上海市超级博士后激励计划
2019.12 上海交通大学优秀毕业生