姓名: 吴疆
性别: 男
民族: 满族
学历: 工学博士
职称: 教授
学科一:机械电子工程
学科二:控制科学与工程
所在院系:山东大学控制科学与工程
研究方向:超声执行器技术,功率超声技术,触觉传感技术,机器人技术
通信地址:济南市经十路17923号山东大学千佛山校区,控制科学与工程学院
社会兼职与荣誉奖励:
IEEE会员,日本声学会会员。
IEEE Transactions on Industrial Electronics, IEEE/ASME Transactions on Mechatronics, Mechanical systems and signal processing, Sensors and Actuators A: Physical, Mechatronics, Journal of Vibration and Control, Ultrasonics等国际期刊审稿人。
2017年入选日本学术振兴会特别研究员(JSPS Research Fellow)人才项目。
研究方向:
超声执行器技术,功率超声技术,触觉传感技术,机器人技术
科研项目:
[1]日本学术振兴会特别研究员(JSPS Research Fellow)人才项目,基于树脂材料超声电机性能的提高. 2017.4-2019.3,190万日元,主持。
[2]东京工业大学-斯巴鲁株式会社校企联合项目,基于新型树脂换能器玻璃表面异物/水滴的去除. 2017.4-2019.3,80万日元,参与。
[3]日本科学研究机关(JST) A-step科研项目,基于新型树脂材料压电执行器的研究. 2015.11-2019.3,1800万日元,参与。
[4]东京工业大学-Daicel株式会社校企联合项目,新型树脂材料声学性能研究及其在超声换能器中的应用. 2012.10-2017.3,400万日元,参与。
SCI期刊论文:
[1]J. Wu, Y. Mizuno, K. Nakamura. Piezoelectric motor utilizing an alumina/PZT transducer. IEEE Transactions on Industrial Electronics, 2020, 67(8), 6762–6772. (SCI,IF: 7.50)
[2]J. Wu, Y. Mizuno, K. Nakamura. A traveling-wave ultrasonic motor utilizing a ring-shaped alumina/PZT vibrator. Smart Materials and Structures, 2019, 28(12), 125017. (SCI,IF:3.54)
[3] M. Slabki,J. Wu, M. Weber, P. Breckner, D. Isaia, K. Nakamura, J. Koruza. Anisotropy of the high-power piezoelectric properties of Pb(Zr, Ti)O3. Journal of the American Ceramic Society, 2019, 102, 3227–3230. (SCI,IF:3.09)
[4]J. Wu, Y. Mizuno, K. Nakamura. Enhancement in mechanical quality factor of poly phenylene sulfide under high-amplitude ultrasonic vibration through thermal annealing. Ultrasonics, 2019, 91, 52–61. (SCI,IF:2.60)
[5]J. Wu, Y. Mizuno, K. Nakamura. Ultrasonic motors with poly phenylene sulfide/alumina/PZT triple-layered vibrators. Sensors and Actuators A: Physical, 2018, 284, 158–167. (SCI,IF:2.74)
[6]J. Wu, Y. Mizuno, K. Nakamura. Vibration characteristics of polymer-based Langevin transducers. Smart Materials and Structures, 2018, 27(9), 095013. (SCI,IF:3.54)
[7]J. Wu, Y. Mizuno, K. Nakamura. Polymer-based ultrasonic motors utilizing high-order vibration modes. IEEE/ASME Transactions on Mechatronics, 2018, 23(2), 788–799. (SCI,IF:4.94)
[8]J. Wu, Y. Mizuno, K. Nakamura. Structural parameter study on polymer-based ultrasonic motor. Smart Materials and Structures, 2017, 26(11), 115022. (SCI,IF:3.54)
[9]J. Wu, K. Hasebe, Y. Mizuno, et al. Magnetic field sensor using a polymer-based vibrator. Measurement Science and Technology, 2016, 27(9), 097002. (SCI,IF:1.86)
[10]J. Wu, Y. Mizuno, M. Tabaru, et al. Measurement of mechanical quality factors of polymers in flexural vibration for high-power ultrasonic application. Ultrasonics, 2016, 69, 74–82. (SCI,IF:2.60)
[11]J. Wu, Y. Mizuno, M. Tabaru, et al. Traveling-wave ultrasonic motor using a polymer-based vibrator. Japanese Journal of Applied Physics, 2016, 55, 018001. (SCI,IF:1.47)
[12]J. Wu, Y. Mizuno, M. Tabaru, et al. Ultrasonic motors with polymer-based vibrators. IEEE Transactions on Ultrasonics, Ferroelectrics, and Frequency Control, 2015, 62(12), 2169–2178. (SCI,IF:3.00)
[13]J. Wu, Y. Mizuno, M. Tabaru, et al. Airborne ultrasonic transducer using polymer-based elastomer with high output-to-weight ratio. Japanese Journal of Applied Physics, 2015, 54, 087201. (SCI,IF:1.47)
