| Smart textile‐integrated microelectronic systems for wearable applications J Shi, S Liu, L Zhang, B Yang, L Shu, Y Yang, M Ren, Y Wang, J Chen, ... Advanced materials 32 (5), 1901958, 2020 | 650 | 2020 |
| A fully verified theoretical analysis of contact‐mode triboelectric nanogenerators as a wearable power source B Yang, W Zeng, ZH Peng, SR Liu, K Chen, XM Tao Advanced Energy Materials 6 (16), 1600505, 2016 | 215 | 2016 |
| Triboelectric charge density of porous and deformable fabrics made from polymer fibers S Liu, W Zheng, B Yang, X Tao Nano energy 53, 383-390, 2018 | 104 | 2018 |
| Highly flexible, large‐area, and facile textile‐based hybrid nanogenerator with cascaded piezoelectric and triboelectric units for mechanical energy harvesting J Song, B Yang, W Zeng, Z Peng, S Lin, J Li, X Tao Advanced Materials Technologies 3 (6), 1800016, 2018 | 97 | 2018 |
| Quantifying energy harvested from contact‐mode hybrid nanogenerators with cascaded piezoelectric and triboelectric units S Chen, X Tao, W Zeng, B Yang, S Shang Advanced Energy Materials 7 (5), 1601569, 2017 | 95 | 2017 |
| Localized deformation in aluminium foam during middle speed Hopkinson bar impact tests B Yang, L Tang, Y Liu, Z Liu, Z Jiang, D Fang Materials science and engineering: A 560, 734-743, 2013 | 46 | 2013 |
| Wireless Multistimulus‐Responsive Fabric‐Based Actuators for Soft Robotic, Human–Machine Interactive, and Wearable Applications R Yin, B Yang, X Ding, S Liu, W Zeng, J Li, S Yang, X Tao Advanced Materials Technologies 5 (8), 2000341, 2020 | 41 | 2020 |
| Monitoring elbow isometric contraction by novel wearable fabric sensing device X Wang, X Tao, RCH So, L Shu, B Yang, Y Li Smart Materials and Structures 25 (12), 125022, 2016 | 36 | 2016 |
| An adhesive surface enables high‐performance mechanical energy harvesting with unique frequency‐insensitive and pressure‐enhanced output characteristics J Gong, B Xu, Y Yang, M Wu, B Yang Advanced Materials 32 (14), 1907948, 2020 | 32 | 2020 |
| Upper limits for output performance of contact-mode triboelectric nanogenerator systems B Yang, X Tao, Z Peng Nano Energy 57, 66-73, 2019 | 32 | 2019 |
| Predicting performance of fiber thermoelectric generator arrays in wearable electronic applications LS Zhang, B Yang, SP Lin, T Hua, XM Tao Nano Energy 76, 105117, 2020 | 26 | 2020 |
| Parametric modeling the human calves for evaluation and design of medical compression stockings W Xi, Y Bao, L Qiao, G Xia, T Xiaoming Computer Methods and Programs in Biomedicine 194, 105515, 2020 | 13 | 2020 |
| 冲击条件下泡沫铝的细观变形特征分析 杨宝, 汤立群, 刘逸平, 黄小清, 刘泽佳, 张纯禹, 魏志强 爆炸与冲击 32 (4), 399-403, 2012 | 10 | 2012 |
| Mesodeformationcharacteristicsanalysisofaluminumfoamunderimpact Y Bao, T Li-qun, LIU Yi-ping, H Xiao-qing 爆炸与冲击 32 (4), 399-403, 2012 | 9 | 2012 |
| Mechanism of the strain rate effect of metal foams with numerical simulations of 3D Voronoi foams during the split Hopkinson pressure bar tests B Yang, ZJ Liu, LQ Tang, ZY Jiang, YP Liu International journal of computational methods 12 (04), 1540010, 2015 | 8 | 2015 |
| The deformation measurement and analysis on meso-structure of aluminum foams during SHPB test B Yang, L Tang, Y Liu, Z Liu, Z Jiang, D Fang Journal of Testing and Evaluation 42 (3), 621-628, 2014 | 7 | 2014 |
| 考虑温度效应的泡沫铝静态压缩本构模型 习会峰, 刘逸平, 汤立群, 刘泽佳, 穆建春, 杨宝 哈尔滨工程大学学报 34 (8), 1000-1005, 2013 | 7 | 2013 |
| 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 魏志强, 黄小清, 杨宝, 汤立群, 和郁伟 实验力学 26 (2), 117-123, 2011 | 7 | 2011 |
| Smart bionic morphing leg mannequin for pressure assement of compression garment XGXMT Bao Yang, Xi Wang, Ying Xiong, Su Liu, Shi-Rui Liu Smart Materials and Structures 29 (25), 055041, 2020 | 6 | 2020 |
| Highly sensitive and durable structured fibre sensors for low-pressure measurement in smart skin B Yang, S Liu, X Wang, R Yin, Y Xiong, X Tao Sensors 19 (8), 1811, 2019 | 6 | 2019 |
Xiaoming TaoChair Professor, The Hong Kong Polytechnic UniversityBestätigte E-Mail-Adresse bei polyu.edu.hk