面向毫克级仿昆扑翼微飞行器的力-力矩传感器
[1] Ma K Y, Felton S M, Wood R J. Design, fabrication, and modeling of the split actuator microrobotic bee[C]// IEEE/RSJ Inter. Conf. on Intelligent Robots & Systems, 2012: 6386192.
[2] Zou Y, Zhang W, Ke X, et al. The design and microfabrication of a sub 100mg insect-scale flapping-wing robot[J]. Micro & Nano Lett., 2017, 12(5): 297-300.
[3] Zou Y, Zhang W, Zhang Z. Liftoff of an electromagnetically driven insect-inspired flapping-wing robot[J]. IEEE Trans. on Robotics, 2016: 1-5.
[4] Zhou S, Zhang W, Zou Y, et al. Piezoelectric driven insect-inspired robot with flapping wings capable of skating on the water[J]. Electron. Lett., 2017, 53(9): 579-580.
[5] Beyeler F, Muntwyler S, Nelson B J. A six-axis MEMS force-torque sensor with micro-newton and nano-newtonmeter resolution[J]. J. of Microelectromechanical Systems, 2009, 18(2): 433-441.
[6] Wood R J, Cho K J, Hoffman K. A novel multi-axis force sensor for microrobotics applications[J]. Smart Materials and Structures, 2009, 18(12): 125002.
[7] Finio B M, Galloway K C, Wood R J. An ultra-high precision, high bandwidth torque sensor for microrobotics applications[C]// Intelligent Robots and Systems (IROS), 2011 IEEE/RSJ Inter. Conf. on, 2011: 6094420.
[8] 高德亮, 范振华. 扭矩传感器原理及应用[J]. 科技传播, 2012(1): 99-107.
Gao Deliang, Fan Zhenhua. The principle and application of torque sensor[J]. Science and Technology Communication, 2012(1): 99-107.
孟冉, 张卫平, 王晨阳, 周岁, 魏铭辰. 面向毫克级仿昆扑翼微飞行器的力-力矩传感器[J]. 半导体光电, 2020, 41(2): 247. MENG Ran, ZHANG Weiping, WANG Chenyang, ZHOU Sui, WEI Mingchen. Lift-Torque Sensor Applied for Insect-Inspired Flapping-Wing Micro Air Vehicle[J]. Semiconductor Optoelectronics, 2020, 41(2): 247.