1. Qishuai Xie, Yunshun Zhang*, Minglei Gao, Influence of Intelligent Connected Signs for Traffic Flow and Lane-Changing Behavior, CVCI 2021, the Invited Session on “Human-Machine Dynamics and Control”, Tianjin University, Oct., 2021. 2. Rencheng Zheng, Zhicen Tang, Chao Liu, Yunshun Zhang, Kai Zheng, Hongyu Hu, Preliminary of Path Planning of Virtual Vehicle for Its Trajectory Control by Eye-Gaze Tracking , CVCI 2021, the Invited Session on “Human-Machine Dynamics and Control”, Tianjin University, Oct., 2021. 3. Yunshun Zhang*, Xiangshuai Zhao*, Xiaoqing Shi, Investigation of self-tuning stochastic resonance by optimizing the rotationally centrifugal distance for energy harvesting, The 3rd International Conference on Vibration and Energy Harvesting Applications, Xian, Shaanxi, Jul., 2021. 4. Yunshun Zhang, Enhancing non-linear vibrations for application to rotating-induced broadband energy harvesting, The 3rd International Conference on Vibration and Energy Harvesting Applications, Xian, Shaanxi, Jul., 2021.(Invited Talk) 5. Yunshun Zhang, Qishuai Xie, Minglei Gao, Yingfeng Cai, and Rencheng Zheng, Self-Controlled In-Vehicle Traffic Light based on The 4th Generation Mobile Communication Technology, IEEE ICM 2021, the Special Session on “Perception and Control of Automated Vehicles”, Kashiwa, Japan, Mar., 2021. 6. Yunshun Zhang, Minglei Gao, Qishuai Xie, Yingfeng Cai, and Rencheng Zheng, In-Vehicle Traffic Light based on Local Area Network, IEEE ICM 2021, the Special Session on “Perception and Control of Automated Vehicles”, Kashiwa, Japan, Mar., 2021. 7. Yunshun Zhang*, and Xiaoqing Shi*, Frequency matching of the centrifugal distance for optimizing the rotating-frequency-range by stabilizing nonlinear oscillations, MoViC2020, ID:10087, Niigata, Japan, Dec., 2020.(Copyright @2020The Japan Society of Mechanical Engineers) 8. Yunshun Zhang*, and Wanshu Wang*, Structure optimization of an asymmetrically conical pendulum for energy harvesting, MoViC2020, ID:10132, Niigata, Japan, Dec., 2020.(Copyright @2020 The Japan Society of Mechanical Engineers) 9. Yunshun Zhang*, et al., Combining sustainable stochastic resonance with high-energy orbitoscillation to broaden rotational bandwidth of energy harvesting from tire, AIP Advances, 2019, DOI: 10.1063/1.5131429 (Copyright @2019 AIP Publishing). 10. Xiaopeng Teng, and Yunshun Zhang*, Maintain high energy orbit by extending nonlinear resonance frequency bandwidth utilising centrifugal effect, Microsystems & Nanoengineering Summit 2019, Chinese Academy of Sciences, July, 2019. 11. Yunshun Zhang*, Rencheng Zheng, Kimihiko Nakano, and Matthew P. Cartmell, Stabilising high energy orbit oscillations by the utilisation of centrifugal effects for rotating-tyre-induced energy harvesting, Applied Physics Letters, 112(14): 143901-1-143901-5, 2018, DOI: 10.1063/1.5019907. (Copyright @2018 AIP Publishing) 12. Yunshun Zhang*, Energy harvesting in a rotating automobile tire enhancing non-linear vibration, International Workshop on Emerging Technology in Mechanical Engineering, Yanshan University, July, 2017. (Invited Speech) 13. Yunshun Zhang*, Rencheng Zheng, Tsutomu Kaiuka, Dongxu Su, Kimihiko Nakano, and Matthew P. Cartmell, Broadband vibration energy harvesting by application of stochastic resonance from rotational environments, The European Physical Journal, 224(14): 2687-2701, 2015, DOI: 10.1140/epjst/e2015-02583-7 (Copyright @2015 EDP Sciences and Springer). 14. Yunshun Zhang*, Rencheng Zheng, Kenji Ejiri, Dongxu Su, and Kimihiko Nakano, Modelling analysis for vibration energy harvesting excited by low-speed automobile tires, Transactions of the JSME, 82(840): 1-11, 2016, DOI: 10.1299/transjsme.15-00645 (In Japanese) (Copyright @2016 The Japan Society of Mechanical Engineers). 15. Yunshun Zhang*, Rencheng Zheng, Keisuke Shimono, Tsutomu Kaizuka, and Kimihiko Nakano, Effectiveness testing of a piezoelectric energy harvester for an automobile wheel using stochastic resonance, Sensors, 16(10): 1727, 2016, DOI: 10.3390/s16101727 (Copyright @2016MDPI AG). 16. Yunshun Zhang*, Rencheng Zheng, and Kimihiko Nakano, Feasibility of energy harvesting from a rotating tire based on the theory of stochastic resonance, Journal of Physics: Conference Series PowerMEMS 2014, 557(1): 012097, Hyogo, Japan, 2014, DOI: 10.1088/1742-6596/557/1/012097 (Copyright @2014 IOP Publications). 17. Yunshun Zhang*, Rencheng Zheng, Tsutomu Kaizuka, and Kimihiko Nakano, Study on tire-attached energy harvester for low-speed actual vehicle driving, Journal of Physics: Conference Series PowerMEMS 2015, 660(1): 012126, Boston, USA, 2015, DOI: 10.1088/1742-6596/660/1/012126 (Copyright @2015 IOP Publications). 18. Yunshun Zhang*, Kimihiko Nakano, Rencheng Zheng, and Matthew P. Cartmell, Adjustable nonlinear mechanism system for wideband energy harvesting in rotational circumstances, Journal of Physics: Conference Series MOVIC & RASD 2016, 744(1): 012079, Southampton, UK, 2016, DOI: 10.1088/1742-6596/744/1/012079 (Copyright @2016 IOP Publications). 19. Yunshun Zhang*, Rencheng Zheng, Kimihiko Nakano, and Matthew P. Cartmell, Energy harvesting from vehicle tires using stochastic resonance, The 4th Korea-Japan Joint Symposium on Dynamics and Control, pp. 106-109, Busan, Korea, May, 2015. 20. Yunshun Zhang*, Rencheng Zheng, Dongxu Su, and Kimihiko Nakano, Modelling analysis for vibration energy harvesting excited by low-speed automobile tires, Dynamics and Design Conference 2015, No.15-7, Hirosaki, Aomori, August, 2015. (In Japanese) 21. 張云順*,淡路創介,永井伸幸,藤倉良充,高橋潤平,橋本誠司,笠井周,須藤健二,岡田宏昭,熊谷俊司(株式会社ミツバ), 振動発電用圧電デバイスの発電特性とインピーダンス整合, 電気学会,ETT-12-52, 宇都宮,2013-03. 22. Michitaka Kawano, Yunshun Zhang, Rencheng Zheng, Kimihiko Nakano, and Beomjoon Kim, Feasibility of energy harvesting using vertical bi-stable cantilever with tip mass based on stochastic resonance, 2015 JSME-IIP/ASME-ISPS Joint Conference on Micromechatronics for Information and Precision Equipment, Kobe, Japan, 2015. 23. Michitaka Kawano, Yunshun Zhang, Rencheng Zheng, Kimihiko Nakano, and Beomjoon Kim, Modelling and fabrication of perpendicular bi-stable cantilever for vibrational energy harvesting grounded on stochastic resonance, Micro and Nano Engineering 2015, Hague, Netherlands, 2015. 24. Michitaka Kawano, Yunshun Zhang, Rencheng Zheng, Kimihiko Nakano, and Beomjoon Kim, Design and manufacture of perpendicular bi-stable cantilever for vibrational energy harvesting on the basis of stochastic resonance, Journal of Physics: Conference Series PowerMEMS 2015, 660(1): 012104, Boston, USA, 2015, DOI: 10.1088/1742-6596/660/1/012104 (Copyright @2015 IOP Publications). 25. Seiji Hashimoto, Yunshun Zhang, Nobuyuki Nagai, et al., Multi-Mode and Multi-Axis Vibration Power Generation Effective for Vehicles, Pro.of IEEE-ISIE2013, Taipei,Taiwan, 2013. 26. 張云順*,藤倉良充,高橋潤平, et al., 自動車振動に対する多モード振動エネルギー回生装置の開発,電気学会,ETT-12-52, 宇都宮,2013-03. 27. 淡路創介,張云順,永井伸幸,et al., 振動発電用圧電デバイスの発電特性とエネルギー回生効率,電気学会,ETT-12-53, 宇都宮大学,2013-03. 28. Amat A. Basari, Sosuke Awaji, Yunshun Zhang, et al., Evaluation of high-efficiency vibration energy regeneration with PZT devices, 第56回自動制御連合講演会,No.333, 新潟,2013-11. 29. Amat A. Basari, Sosuke Awaji, Yunshun Zhang, et al., Comparison and evaluation of vibration-based piezoelectric power generators, International Power Electronics Conference (IPEC-Hiroshima 2014 - ECCE ASIA), Hiroshima, 2014-05. 30. 王松,張云順,Amat A. Basari, et al., 振動発電用圧電デバイスの最適形状に関する研究,電気学会,ETT-14-33, 群馬,2014-03. 31. 淡路創介,張云順,藤倉良充,et al., 振動発電用圧電デバイスのインピーダンス整合とエネルギー回生効率,平成25年電気学会,Y-65, 山口,2013-08. 32. 淡路創介,張云順,藤倉良充,et al., 振動発電用圧電デバイスのインピーダンス整合とエネルギー回生効率,高分子学会,群馬,2013-03. |