单胜博，助理教授，硕士生导师

电子邮箱/Email：shanshengbo@tongji.edu.cn

电话/Telephone：15195950044

教育经历/Education：

2008-09至2012-06，南京航空航天大学，飞行器设计与工程，学士

2012-09至2015-03，南京航空航天大学，飞行器设计，硕士

2015-07至2019-03，香港理工大学，机械工程，博士

工作经历/Employment：

2017-10至2018-01，宾夕法尼亚州立大学，访问学者

2019-03至2021-05, 香港理工大学，机械工程学系，博士后

2021-05至今, 同济大学，航空航天与力学学院，助理教授

主要研究方向/Research Interests：

1. 非线性导波理论

理论研究工程结构中不同形式的非线性导波的产生机理与传播特点。

2. 智能传感器技术

基于压电、磁致伸缩、电磁等原理，研究用于导波激励与接收的传感器设计与封装。

3. 结构健康监测算法

开发基于信号处理与数据挖掘的算法，利用传感器数据评估结构的健康状态。

4. 弹性波超材料研究

设计基于超材料的功能器件，用于定制与操控结构中的导波传播。

主讲课程/Courses Teaching：

飞行动力学

MATLAB应用

期刊论文列表/Peer Reviewed Publications：

1. Shan S*, Zhang Y, Liu Z, Wen F, Cheng L*, Staszewski W. Cross-modulation in guided wave propagation: how does it relate to the Luxemburg-Gorky effect?. Journal of Sound and Vibration, 2024, 568: 117961.

2. Zhang Y, Shan S*, Cheng L*. Elastic wave propagation in thick-walled hollow cylinders for damage localization through inner surface sensing. Ultrasonics, 2023: 107027. 

3. Liu Z, Shan S, Cheng L*. Nonlinear-Lamb-wave-based plastic damage detection assisted by topologically designed metamaterial filters. Structural Health Monitoring, 2023, 22(3): 1828-1843. 

4. Shan S, Liu Z, Cheng L*, Pan Y. Metamaterial-enhanced coda wave interferometry with customized artificial frequency-space boundaries for the detection of weak structural damage. Mechanical Systems and Signal Processing, 2022, 174: 109131. 

5. Shan S, Cheng L*. Two-dimensional scattering features of the mixed second harmonic A0 mode Lamb waves for incipient damage localization. Ultrasonics, 2022, 119: 106554.

6. Shan S, Pan Y*, Xiao S. An efficient damage quantification method for cylindrical structures enhanced by a dry-point-contact torsional-wave transducer. Applied Sciences, 2022, 12(2): 572.

7. Liu Z Shan S, Dong H, Cheng L* Topologically customized and surface-mounted meta-devices for Lamb wave manipulation. Smart Materials and Structures, 2022, 31(6): 065001. 

8. Wen F, Shan S, Cheng L*. Immunity of the second harmonic shear horizontal waves to adhesive nonlinearity for breathing crack detection. Structural Health Monitoring, 2022;21(5):2340-2353.

9. Shan S, Wen F, Cheng L*. Purified nonlinear guided waves through a metamaterial filter for inspection of material microstructural changes. Smart Materials and Structures, 2021, 30(9): 095017. 

10. Wen F, Shan S, Radecki R, Staszewski W, Cheng L*. Shear-lag modelling of surface-bonded magnetostrictive transducers for shear horizontal wave generation in a non-ferromagnetic plate. Smart Materials and Structures, 2021, 30(3): 035026. 

11. Wen F, Shan S, Cheng L*. Third harmonic shear horizontal waves for material degradation monitoring. Structural Health Monitoring, 2021, 20(2): 475-483.

12. Shan S, Cheng L*. Mode-mixing-induced second harmonic A0 mode Lamb wave for local incipient damage inspection. Smart Materials and Structures, 2020, 29(5): 055020. 

13. Shan S, Cheng L*. Mixed third harmonic shear horizontal wave generation: interaction between primary shear horizontal wave and second harmonic lamb wave. Smart Materials and Structures, 2019, 28, 085042.

14. Shan S, Hasanian M, Cho H, Lissenden C*, Cheng L. New nonlinear ultrasonic method for material characterization: Codirectional shear horizontal guided wave mixing in plate. Ultrasonics, 2019, 96: 64-74.

15. Li P, Shan S, Wen F, Cheng L*. A Fully-Coupled Dynamic Model for the Fundamental Shear Horizontal Wave Generation in a PZT Activated SHM System, Mechanical Systems and Signal Processing, 2019, 116, 916-932. 

16. Cho H, Hasanian M, Shan S, Lissenden C*. Nonlinear guided wave technique for localized damage detection in plates with surface-bonded sensors to receive Lamb waves generated by shear-horizontal wave mixing. NDT & E International, 2019, 102: 35-46.

17. Shan S, Cheng L*, Wen F. Design of nonlinear-Lamb-wave-based structural health monitoring systems with mitigated adhesive nonlinearity, Smart Materials and Structures, 2018, 27(10), 105006.

18. Shan S, Cheng L*, Wen F. Characterization of nonplanar second harmonic lamb waves with a refined nonlinear parameter. Journal of Nondestructive Evaluation, Diagnostics and Prognostics of Engineering Systems, 2018, 1(1): 011004.

19. Xiao Z, Shan S, Cheng L*. Identification of cascade dynamic nonlinear systems: a bargaining game theory based approach, IEEE Transactions on Signal Processing, 2018, 66(17), 4657-4669.

20. Shan S, Cheng L*, Li P. Adhesive nonlinearity in Lamb-wave-based structural health monitoring systems. Smart Material and Structures, 2017, 26(2):025019.

21. Shan S, Qiu J*, Zhang C, Ji H, Cheng L. Multi-damage localization on large complex structures through an extended delay-and-sum based method. Structural Health Monitoring, 2016, 15(1): 50-64.

22. Zhang C, Qiu J*, Ji H, Shan S. An imaging method for impact localization using metal-core piezoelectric fiber rosettes. Journal of Intelligent Material Systems and Structures, 2015, 26(16): 2205-2215.

23. Zhang C, Qiu J*, Ji H, Shan S. Damage localization using warped frequency transform in active structural health monitoring. International Journal of Applied Electromagnetics and Mechanics, 2015, 47(4): 897-909. 

科研项目/Projects：

1. 国家自然科学基金青年科学基金，基于多功能超表面的复合材料板中非线性导波调控研究，30万元，2024年1月-2026年12月，主持。

2. 上海市自然科学基金面上项目, 复合材料板中的非线性导波研究：从机理特征到早期损伤监测, 2022-04 至 2025-03, 20万元, 主持

3. 上海市科学技术委员会, 上海市领军人才（海外）项目, 2022-01 至 2024-12, 120万元,主持

学术期刊审稿/Journal Reviewer：

NDT&E International, Structural Health Monitoring, Ultrasonics，Journal of the Acoustical Society of America等