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更新日期：2023年4月12日 姓 名 杨宝 性 别 男 出生年月 1983年2月 籍贯 广东信宜市 民 族 汉族 政治面貌 中国共产党党员 最后学历 博士研究生毕业 最后学位 工学博士 技术职称 副教授 导师类别 博导 行政职务 Email byang20210415@scut.edu.cn 工作单位 华南理工大学土木与交通学院力学系 邮政编码 510640 通讯地址 广州市天河区五山路381号交通大楼304室 单位电话 020-87111030-3304 个人主页 http://yanzhao.scut.edu.cn/Open/TeacherOpen/TeacherInfo.aspx?jsbh=20211007 个人简介 杨宝，男，汉族，广东人，中共党员。2007年毕业于华南理工大学工程力学，获工学学士学位；2012年毕业于华南理工大学固体力学专业，获工学博士学位（获校优秀博士论文奖，导师：汤立群教授）。2013年至2021年，香港理工大学纺织与服装学系及智能可穿戴中心工作，担任博士后研究员/副研究员/研究员（导师：陶肖明教授（国际纺织学会荣誉院士、获美国纤维学会最高个人奠基者奖和第十三届光华工程科技奖等获得者）；2021年6月通过海外人才引进计划入职华南理工大学大学交通学院工程力学系。现任华南理工大学副教授，广东省力学学会生物力学专委会委员、广东省力学学会爆炸力学与工程爆破专委会委员、广东省生物医学工程学会生物力学专委会委员。主要研究方向为材料动态力-电机理、柔性传感技术、智能可穿戴设备、运动生物力学以及它们在运动与康复医疗领域的应用。主持或参与国家自然科学基金项目（重点项目1项，面上项目2项目）、国家重点研发计划（2项）、香港创新及科技基金项目（4项）和香港基础研究基金项目（3等）及其企业委托项目多项。在国际权威期刊发表SCI论文40余篇（近五年JCR Q1>20篇，包括Advance Energy Materials, Nano Energy, EcoMat等），被引用1千余次（Google scholar citations）。应邀担任 Smart Materials and Structures、Fibres and  Polymers、 Journal of Micromechanics and Microengineering、 Mechanics of Advanced Materials and Structures 等多家国际学术期刊的通讯审稿人。长期招收固体力学方向博士后（特别有交叉力学研究和智能可穿戴设备研究经验者），有兴趣的同学请发简历至byang20210415@scut.edu.cn。 工作经历 2021-06 至今，华南理工大学土木与交通学院，副教授/博士生导师 2020-06至 2021-05，香港理工大学， 纺织与服装学系，研究员（导师：陶肖明教授）2013-12至2020-06，香港理工大学， 纺织与服装学系，副研究员（导师：陶肖明教授）2013-06 至 2013-12，香港理工大学， 纺织与服装学系，博士后研究员（导师：陶肖明教授） 教育经历 2007.09 - 2012.12   华南理工大学  固体力学博士学位2003.09 - 2007.09  华南理工大学   工程力学学士学位 获奖、荣誉称号 华南理工大学优秀博士毕业论文（ 2014年） 社会、学会及学术兼职 广东省力学学会生物力学专委会委员广东省力学学会爆炸力学与工程爆破专委会委员广东省生物医学工程学会生物力学专委会委员。担任 Smart Materials and Structures、Fibres and  Polymers、 Journal of Micromechanics and Microengineering、 Mechanics of Advanced Materials and Structures 等多家国际学术期刊的通讯审稿人 研究领域 核心研究方向和兴趣：材料动态力-电机理、柔性传感技术、智能可穿戴设备、运动生物力学以及它们在运动与康复医疗领域的应用。 科研项目 1. 国家自然科学基金面上项目，石墨炔基柔性电化学驱动器的制备、介观调控及换能特性研究，21975217，2020.01 - 2023.12，65万，在研， 参与2. 国家自然科学基金重点专项，溶液环境中高含水率超软材料动态性能的实验技术与表征方法，2018YFC2000904，2019.01-2023.12，367.65万，在研，参与3. 企业单位委托项目，基于深度学习的地基溶洞探测技术研究，48万，2022-2023，在研，负责人4. 华南理工大学人才队伍建设经费-杨宝，40万, 2021.06 - 2027.05，在研，负责人5. 国家重点研发计划，主动健康和人口老龄化科技应对，多源信息融合的心肺功能评测康复关键技术及有效集成研究，2022YFC3601000，2022.12 - 2025.12，在研，研究骨干（课题二华南理工大学负责人） 6. 中国香港创新及科技基金，Trial：Intelligent Wearable System for Enhancing Mobility of People with Parkinson’s Disease (Easypacer) 应用智能可穿戴系统（颐步）改善帕金森症患者活动能力,  ITT/023/18TP，2019.03 - 2020.12，330万港币，结题，研究骨干7. 中国香港创新及科技基金，Fabric Sensors for Three-Dimensional Surface Pressure Mapping织物传感器测量三维压力分布，ITT/035/14TP. K-ZRJG，2016.04 – 2016.09，803万港币，结题，参与8. 中国香港创新及科技基金，Key Technologies of Customized Intelligent Medical Pressure Clothing 智能医用压力服装量身定制关键技术,  ITP/041/19TP，2020.03 - 2022.09，866.7万港币，结题，研究骨干9. 中国香港大学教育资助委员会，Hybridization of textile-based Piezoelectric and Triboelectric Nanogenerators 织物基杂化摩擦电-压电纳米发电机，15200917，2018.01 - 2020.12，87.5万港币，结题，参与10. 中国香港大学教育资助委员会，Multi-scaled study of Triboelectric Effects in Textile Structures多尺度研究织物结构摩擦电效应, 15211016，2017.01 - 2019.12，67.5万港币，结题，研究骨干11. 中国香港大学教育资助委员会，Structures and Transport Properties Thermoelectric Textile Composite 热电织物复合材料的结构和传输性能15204715，2015.01 - 2019.04，49.6万港币，结题，参与12. 中国香港理工大学研究基金，Textile Based Energy Harvesting and Storage Systems-an Exploratory Study 织物基能源收集及存储系统研究，1-BBA3，2016.01 - 2018.12，25万港币，结题，研究骨干13. 中国香港创新及科技基金，Novel Bio-based Anti-bacteria Textile for Healthcare Application 新型生物基抗菌纺织品的健康护理应用技术, ITP/039/16TP，2016.10-2018.10，1054万港币，结题，研究骨干14. 中国香港大学教育资助委员会，Tribological Study of Textile-based Wearable Electronic Devices，15215214，2014.12-2018.12，87.5万港币，结题，参与15. 中国香港创新及科技基金，Manufacturing Technologies for Green Textiles with High Added Values 高附加值绿色纤维的制备加工技术， ITP/050/13，2014.03-2016.03，618万港币，结题，参与16. 中国香港大学教育资助委员会，Study of Fiber-based Wearable Electric Power Generators 纤维基可穿戴式发电装置，525113，2013.12 - 2017.06，83.6万港币，结题，参与17. 国家自然科学基金委员会及研究资助局联合科研资助基金，The Key Technologies of Deformable Bionic Search Robots with Electric Fabric Skin电子织物皮肤的可变形仿生搜救机器人关键技术研究，N-PolyU503/12，2013.01 - 2016.12, 102.8万港币，结题，参与18. 中国香港创新及科技基金项目，举重运动员中的运动生理信号和机械信号智能监测系统，ITT/011/11TT，203万港币，结题，参与 发表论文 代表性论文（部分）2023年Chengbin Chen, Liqun Tang, Yonghui Lu, Yong Wang, Zejia Liu, Yiping Liu and Licheng Zhou*, Zhenyu Jiang, Bao Yang, 2023，Reconstruction of long-term strain data for structural health monitoring with a hybrid deep-learning and autoregressive model considering thermal effects. Engineering Structures, ,285:116063. (IF = 5.582, Q1)https://doi.org/10.1016/j.engstruct.2023.116063Yonghui Lu, Liqun Tang, Chengbin Chen, Licheng Zhou*, Zejia Liu, Yiping Liu, Zhenyu Jiang, Bao Yang, 2023, Reconstruction of structural long-term acceleration response based on BiLSTM networks. Engineering Structures, 285:116000. (IF = 5.582, Q1)https://doi.org/10.1016/j.engstruct.2023.116000Chengbin Chen, Liqun Tang, Yonghui Lu, Licheng Zhou*, Zejia Liu, Yiping Liu, Zhenyu Jiang, Bao Yang, 2023, Temperature-induced response reconstruction method based on DL-AR model and attention mechanism. Structures, 50: 356-372. (IF = 4.010, Q2)https://doi.org/10.1016/j.istruc.2023.02.044 周颖，刘泽佳，张舸，周立成，刘逸平，汤立群，蒋震宇，杨宝，2023，基于移动主成分分析与集成学习的结构损伤识别方法，济南大学学报(自然科学版)，01:1671-3559. https://doi.org/10.13349/j.cnki.jdxbn.20221103.002 Yibing Xie, Zihao Wang, Xiaoyue Ren, Maxwell Fordjour Antwi-Afari, Yameng Wang, Hao-Yang Mi*, Bao Yang*, Chuntai Liu*, Changyu Shen, 2023, An internal electrode strategy for enhancing the stability and durability of triboelectric nanogenerator. Composites Science and Technology. 237:110014. (IF = 9.879, Q1)https://doi.org/10.1016/j.compscitech.2023.110014Jun Li, Ying Xiong, Kitming Ma, Bao Yang, Linlin Ma, Xiaoming Tao*, 2023, Asymmetric strategy for enhanced performance of flexible electroadhesive clutch. Heliyon, 9(2): e12938. (IF = 3.776, Q2)https://doi.org/10.1016/j.heliyon.2023.e12938 Jingyu Wang, Yongrou Zhang, Zhenyu Jiang, Licheng Zhou*, Zejia Liu, Yiping Liu, Bao Yang, and Liqun Tang*, 2023, Mechanical behavior and constitutive equations of porcine brain tissue considering both solution environment effect and strain rate effect. Mechanics of Advanced Materials and Structures, 1-15. (IF = 3.338, Q2)https://doi.org/10.1080/15376494.2022.2150917 Xiaoyang Zhang, Liqun Tang*, Bao Yang, Heping Hu, Shifeng Tan, 2023, Study on the effect of the size irregularity gradient of metal foams on macroscopic compressive properties. Heliyon, 8(12): e12531. (IF = 3.776, Q2)https://doi.org/10.1016/j.heliyon.2022.e12531 Kai He, Huanchen Liao, Zejia Liu, Yiping Liu, Liqun Tang, Bao Yang, Licheng Zhou*, Zhenyu Jiang*, 2023, Reinforcing efficiency of nanophases with various geometric shapes on interfacial bonding in multiscale composites. Composites Part A-APPLIED SCIENCE AND MANUFACTURING ,165:107369. (IF = 9.463, Q1)https://doi.org/10.1016/j.compositesa.2022.107369 2022年Chang Peng, Chang Liu, Zhenhao Liao, Bao Yang, Liqun Tang, Lei Yang*, Zhenyu Jiang*. 2023, Automatic 3D image based finite element modelling for metallic foams and accuracy verification of digital volume correlation. International Journal of Mechanical Sciences, 2022, 235: 107715. (IF =6.772, Q1)https://doi.org/10.1016/j.ijmecsci.2022.107715   Shuping Lin, Lisha Zhang, Wei Zeng, Dongliang Shi, Su Liu, Xujiao Ding, Bao Yang, Jin Liu, Kwok-ho Lam, Baolin Huang, Xiaoming Tao*. 2022, Flexible thermoelectric generator with high Seebeck coefficients made from polymer composites and heat-sink fabrics. Communications Materials, 3(1): 1-13. (Q1)https://doi.org/10.1038/s43246-022-00263-1 Bao Yang, Ying Li, Fei Wang, Stephanie Auyeung, Manyui Leung, Margaret Mak, Xiaoming Tao*. 2022, Intelligent wearable system with accurate detection of abnormal gait and timely cueing for mobility enhancement of people with Parkinson’s disease. Wearable Technologies, 3, E12. https://doi.org/10.1017/wtc.2022.9 Haiyan Fu, Jianliang Gong*, Hao Zhong, Bao Yang, Zuchang Long, Jiqing Zeng, Zhiyu Cheng, Jialin He, Bingang Xu and Yiwang Chen*. 2022, Surface microstructural engineering of silicone elastomers for high performance adhesive surface-enabled mechanical energy harvesters. Journal of Materials Chemistry A, 10(17): 9643-9654. (IF =14.511, Q1)https://doi.org/10.1039/D2TA00343K 2021年Su Liu, Kitming Ma, Bao Yang, Heng Li, Xiaoming Tao*. 2021.Textile Electronics for VR/AR Applications. Advanced Functional Materials, 2007254 (IF = 16.836, Q1)https://doi.org/10.1002/adfm.202007254 陶肖明，刘苏，杨宝，张莉莎，马洁明，舒琳和王飞. 织物电子器件及系统的发展现状、科学问题、核心技术和应用展望，科学通报，2021, 66(24): 3071-3087. Xiaoming Tao*, Su Liu, Bao Yang, Lisha Zhang, Kitming Ma, Lin Shu, Fei Wang. 2021, Recent advances, scientific issues, key technologies and perspective of textile electronics. Chinese Science Bulletin, 66(24): 3071 – 3087. (Q3)https://doi.org/10.1360/TB-2020-1402 Su Yang，Su Liu, Xujiao Ding, Bo Zhu, Jidong Shi, Bao Yang, Shirui Liu Wei Chen, Xiaoming Tao*. 2021. Permeable and washable electronics based on polyamide fibrous membrane for wearable applications. Composites Science and Technology, 207:108729 (IF = 7.094, Q1)  https://doi.org/10.1016/j.compscitech.2021.108729 Xi Wang#, Bao Yang#, Qiao Li, Fei Wang, Xiaoming Tao. 2021. Modeling the stress and resistance relaxation of conductive composites-coated fabric strain sensors. Composites Science and Technology, 204:108645. (IF = 7.094, Q1, Co-first author)https://doi.org/10.1016/j.compscitech.2021.108645 Bao Yang, Ying Xiong, Kitming Ma, and Xiaoming Tao*. 2020. Recent advances in wearable textile‐based triboelectric generator systems for energy harvesting from human motion.  EcoMat. 2(4): e12054 (IF = 12.213, Q1)https://doi.org/10.1002/eom2.12054 2020年Lisha Zhang, Bao Yang, Shuping Lin, Tao Hua, Xiaoming Tao*. 2020, Predicting performance of fiber thermoelectric generator arrays in wearable electronic applications. Nano Energy, 76:105117. (IF = 15.584, Q1)https://doi.org/10.1016/j.nanoen.2020.105117 Rong Yin#, Bao Yang#, Xunjiao Ding, Su Liu, Wei Zeng, Jun Li, Su Yang, and Xiaoming Tao*. 2020. Wireless Multistimulus‐Responsive Fabric‐Based Actuators for Soft Robotic, Human–Machine Interactive, and Wearable Applications, Advanced Materials Technologies, 5(8): 2000341.  (IF = 5.969, Q1, Co-first author)https://doi.org/10.1002/admt.202000341 Xi Wang, Bao Yang, Li Qiao, Xia Guo, and Xiaoming Tao*. 2020. Parametric Modeling the Human Calves for Evaluation and Design of Medical Compression Stockings. Computer Methods and Programs in Biomedicine, 194: 105515. (IF = 3.424, Q1)https://doi.org/10.1016/j.cmpb.2020.105515 Jianliang Gong, Bingang Xu*, Yujue Yang, Mengjie Wu, Bao Yang. 2020. An Adhesive Surface Enables High-Performance Mechanical Energy Harvesting with Unique Frequency-Insensitive and Pressure-Enhanced Output Characteristics, Advanced Materials, 32(14): 1907948. (IF = 27.398, Q1)https://doi.org/10.1002/adma.201907948 Bao Yang#, Xi Wang#, Ying Xiong, Shirui Liu, Xia Guo, and Xiaoming Tao*. 2020. Smart Bionic Morphing Leg Mannequin for Pressure Assessment of Compression Garment, Smart Materials and Structures, 29(5): 055041. (IF = 3.613, Q1)https://doi.org/10.1088/1361-665X/ab7856 2019年Jidong Shi, Su Liu, Lisha Zhang, Bao Yang, Lin Shu, Ying Yang, Ming Ren, Yang Wang, Jiewei Chen, Weu Chen*, Yang Chai*, Xiaoming Tao*. 2019. Smart Textile‐Integrated Microelectronic Systems for Wearable Applications, Advanced Materials,32(5):1901958. (IF = 27.398, Q1)https://doi.org/10.1002/adma.201901958 Bao Yang, Su Liu, Xi Wang, Rong Yin, Ying Xiong, and Xiaoming Tao*. 2019. Highly Sensitive and Durable Structured Fibre Sensors for Low-Pressure Measurement in Smart Skin. Sensors, 19(8): 1811. (IF = 3.275, Q1)https://doi.org/10.3390/s19081811 Bao Yang, Xiaoming Tao*, and Zehua Peng. 2019. Upper limits for output performance of contact-mode triboelectric nanogenerator systems, Nano Energy, 57:66-73. (IF = 16.602, Q1)https://doi.org/10.1016/j.nanoen.2018.12.013 2018年以前Shirui Liu, Wei Zheng, Bao Yang, and Xiaoming Tao*. 2018. Triboelectric charge density of porous and deformable fabrics made from polymer fibers. Nano Energy, 53: 383-390, (IF = 16.602, Q1)https://doi.org/10.1016/j.nanoen.2018.08.071 Jian Song, Bao Yang, Wei Zeng, Zehua Peng, Shuping Lin, Jun Li and Xiaoming Tao*. 2018. Highly Flexible, Large-Area and Facile Textile-Based Hybrid Nanogenerator with Cascaded Piezoelectric and Triboelectric Units for Mechanical Energy Harvesting, Advanced Materials Technologies, 3(6):1800016. (IF = 5.969, Q1)https://doi.org/10.1002/admt.201800016 Song Chen, Xiaoming Tao*, Wei Zeng, Bao Yang, and Songmin Shang. 2017. Quantifying Energy Harvested from Contact-Mode Hybrid Nanogenerators with Cascaded Piezoelectric and Triboelectric Units, Advanced Energy Materials, 7(5): 1601569, P.1-9.  (IF = 25.245, Q1)https://doi.org/10.1002/aenm.201601569 Xi Wang, Xiaoming Tao*, RCH So, Lin Shu, Bao Yang, and Ying Li. 2016. Monitoring Elbow Isometric Contraction by Novel Wearable Fabric Sensing Device, Smart Materials and Structures, 25(12):125022. (IF = 3.613, Q1)https://doi.org/10.1088/0964-1726/25/12/125022 Bao Yang, Wei Zeng, Zehua Peng, Shirui Liu, Ke Chen, and Xiaoming Tao*. 2016. A Fully Verified Theoretical Analysis of Contact-Mode Triboelectric Nanogenerators as a Wearable Power Source, Advanced Energy Materials, 6(16):1600505. (IF = 25.245, Q1)https://doi.org/10.1002/aenm.201600505 Bao Yang, Zejia Liu, Liqun Tang, Zhenyu Jiang and Yiping Liu*, 2015. Mechanism of the Strain Rate Effect of Metal Foams with Numerical Simulations of 3D Voronoi Foams during the Split Hopkinson Pressure Bar Tests, International Journal of Computational Methods, 12(04):1540010. (IF = 1.716, Q3)https://doi.org/10.1142/S0219876215400101 Bao Yang, Liqun Tang*, Yiping Liu, Zejia Liu, Zhenyu Jiang and Daining Fang. 2014. The Deformation Measurement and Analysis on Meso-Structure of Aluminium Foams during SHPB Tests, Journal of Testing and Evaluation, 42(3):621-628. (IF = 0.877, Q4)https://doi.org/10.1520/JTE20120254 Bao Yang, Liqun Tang*, Yiping Liu, Zejia Liu, Zhenyu Jiang and Daining Fang, 2013. Localized Deformation in Aluminium Foam during Middle Speed Hopkinson Bar Impact Tests, Materials Science and Engineering A, 560:734-743. (IF = 3.414, Q2)https://doi.org/10.1016/j.msea.2012.10.027 Chunyu Zhang, Liqun Tang, Bao Yang, Lue Zhang, Xiaoqing Huang, and Daining Fang, 2013. Meso-mechanical study of collapse and fracture behaviors of closed-cell Metallic foams, Computational Materials Science, 79:45-51. (IF = 2.863, Q2)https://doi.org/10.1016/j.commatsci.2013.05.046 习会峰, 刘逸平, 汤力群, 刘泽佳, 穆建春, 杨宝, 2013, 考虑温度效应的泡沫铝准静态压缩本构模型, 哈尔滨工程大学学报, 34(8):1-6. (EI)https://doi.org/10.3969/j.issn.1006-7043.201211022 杨宝，汤立群*，刘逸平，刘泽佳， 黄小清，张纯禹和魏志强，2012. 冲击条件下泡沫铝的细观变形特征分析, 爆炸与冲击, 32(4): 399-403. (EI)https://doi.org/10.11883/1001-1455(2012)04-0399-05 魏志强, 黄小清, 杨宝, 汤立群, 和郁伟, 2011, 应用高速摄影机对泡沫铝在SHPB实验过程的变形跟踪与分析, 实验力学, 26:1-7. (EI) http://doi.org/1001-4888(2011)02-0117-07  Zhiqiang Wei, Xiaoqing Huang, Bao Yang, Liqun Tang, Yuwei He. 2011, Tracking and Analysis of Aluminum Foam Deformations in SHPB Experiment by Using High-speed Camera[J]. Journal of Experimental Mechanics, 26(2): 117-123.http://doi.org/1001-4888(2011)02-0117-07    Lohan Peng*, Huiliang Zhang, Bao Yang, Liqun Tang, Philip Hemmer, Hong Liang, 2010. Stress-Induced Nanostructures through Laser-Assisted Scanning Probe Nanolithography, The Journal of Scanning Microscopies, 32 (5): 327-335. (IF = 1.330, Q3)https://doi.org/10.1002/sca.20198 刘泽佳, 李保木, 杨宝, 汤立群. 2008, 在役桥梁中混凝士材料的徐变监测与分析. 中山大学学报(自然科学版），S2: 5-8. (Zejia Liu, Baomu Li, Bao Yang, Liqun Tang. 2008, The monitoring and analysis on the concrete creep behaviours of a serviced bridge. Acta Scientiarum Naturalium Universitatis Sunyatseni, 47(SUPPL. 2) ：5-8.)会议论文（部分）1. Yang B., Chen K., Zeng W., Peng Z. H., Liu S. R. and Tao XM, An experimentally verified theoretical study and optimization for contact-mode triboelectric nanogenerators, 14th Asian Textile Conference, Hong Kong, 28~30 Jun., 20172. Chen S., Tao XM, Zeng W., Yang B. and Shang S.M., High power output of hybrid nanogenerators with triboelectric and piezoelectric units, 14th Asian Textile Conference, Hong Kong, 28~30 Jun., 20173. Yang B., Chen K, Zeng W, Peng ZH, Liu SR and Tao XM, Optimization of vertical contact-mode Triboelectric nanogenerators based on a fully verified model, Small sciences symposium flexible and wearable devices, Hong Kong, May 14-17,20174. Yang B, Zeng W, Peng ZH, Liu SR, Chen K, Tao XM, Optimization design of contact-mode triboelectric nanogenerators with fully verified theoretical treatment, 3rd International Conference on Nanogenerators and Piezotronics, Rome, Italy, June 15-17 ,20165. Bao Yang, Xiaoming Tao, Fully verified theoretical treatment of contact-mode TENGs as a wearable energy source, 5th Conference of Wearable Computing, Harbin Institute of Technology, 29-30 June 2016.6. Zeng W, Yang B and Tao XM, Low-cost triboelectric generator based on flexible conducting fabric electrodes, The 2nd International Conference on Nanogenerator and piezoelectronics, June 6-11, 2014, Atlanta, USA.7. Yang B, Zeng W, Chen S, Song J, Liu SR, Lin SP, Zhang LS, Tao XM, Fiber-based Hybrid Energy Conversion Systems, 2019 MRS Meeting Spring, Pheonix, USA, 22-27 April 2019.8. Tao XM, Yang B, High output power of contact-separation mode triboelectric nanogenerators by efficiently boosting the surface charge density and charge transfer, 4th International Conference on Nanogenerators and Piezotronics, Seoul, Korea. 7-11 May, 2018. (invited)9. Tao XM, Wang X, So R, Li Y and Yang B, A smart wearable monitoring system for sports based on a new bio-mechanical model for elbow flexions, The 8th Textile Conference Cross Straits, Taichung, 27 May 2017.10. Tao XM, Wang X, So R, Yang B and Li Y, Electronic Fabric Enabled Wearable Monitoring System for Muscle Contraction in Sports of Elbow Flexions, ICMAT 2017, Singapore, 17-23 June 2017.11. Tao XM, Yang B, Zeng W, Liu SR, Fundamental Study of Fiber-based Flexible Electronics and Photonics, National Conference of Chemical Society of China, Dalian, 1-4 July 2016.12. Yang B, Yu TX, Tao XM, Dynamic Strain Sensing Behavior of Fabric Sensors Coated with Carbon Elastomer Composites, MRS Spring meeting, Phoenix, USA, 29 March to 1 April, 2016.13. Yang B, Liu ZJ, Tang LQ, Jiang ZY, Liu YP, Mechanisms of strain rate effect of metal foams with numerical simulations of 3D Voronoi foams during SHPB tests, APCOM&ISCM, January 2013, Singapore.更多成果请参见：ORCID：https://orcid.org/0000-0003-3638-0212ResearchGate：https://www.researchgate.net/profile/Bao-Yang-10Google Scholar：https://scholar.google.com/citations?user=2jONmJkAAAAJ&hl=en 科研创新 专利1. Tao XM, Yang B, Wang X., Bionic leg mannequins and fabrication method, Chinese invention patent and PCT application. 2019，201910139406.0.2. Tao XM, Yang B, Wang X, Liu S, Guo X, Liu SR, INTELLIGENT BIONIC HUMAN BODY PART MODEL DETECTION DEVICE AND METHOD FOR MANUFACTURING SAME, United States Patent Application Publication, US 2021/0010877 A13. 林建生，刘逸平，汤立群，蒋震宇，刘泽佳，周立成，杨宝，基于眼压计压头受力的判定压头达到压平的方法，发明专利，申请号：202111421869X4. 林建生，刘逸平，汤立群，蒋震宇，刘泽佳，周立成，杨宝，基于眼压计压头受力的判定压头达到压平的方法，PCT或外国专利，申请号：PCT/CN2022/0829845. 刘逸平，吕苏磊，汤立群，蒋震宇，刘泽佳，周立成，杨宝，基于真实眼球环境的仿生眼球结构及其测试系统，发明专利，申请号：20221105127826. 汤立群，刘泽佳，刘逸平，何庭蕙，张红，张纯禹，陈金明，桑登峰，杨宝，蒋斌，埋入式双层封装光纤光栅传感器，实用新型，申请号：20122010999327. 汤立群，刘泽佳，刘逸平，何庭蕙，张红，张纯禹，陈金明，桑登峰，杨宝，蒋斌，埋入式双层封装光纤光栅传感器及其制作方法，发明专利，申请号：20121007716118. 王敬谕，孙桃林，汤立群，张泳柔，刘逸平，蒋震宇，刘泽佳，周立成，杨宝，制作实物仿脑模型的透明SA-DN-NP复合凝胶材料的制备方法，发明专利，申请号：20221062840169. 陶肖明，朴金丽，杨宝，光纤传感器及摩擦系数的测量方法，发明专利，申请号：202211491815.5 （Fiber Optic Sensor and Method for Measurement of Friction Coefficient） 教学活动 主讲《弹性力学》、《理论力学》与《航空航天力学概论及力学应用》等课程。 指导学生情况 目前指导博士研究生（2名在读），硕士研究生（4名在读）