J4 ›› 2014, Vol. 11 ›› Issue (4): 541-555.doi: 10.1016/S1672-6529(14)60066-4

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A Bio-Inspired Hopping Kangaroo Robot with an Active Tail

Guan-Horng Liu, Hou-Yi Lin, Huai-Yu Lin, Shao-Tuan Chen, Pei-Chun Lin   

  1. Department of Mechanical Engineering, National Taiwan University, Taipei 106, Taiwan
  • 出版日期:2014-09-30
  • 通讯作者: Pei-Chun Lin E-mail:peichunlin@ntu.edu.tw

A Bio-Inspired Hopping Kangaroo Robot with an Active Tail

Guan-Horng Liu, Hou-Yi Lin, Huai-Yu Lin, Shao-Tuan Chen, Pei-Chun Lin   

  1. Department of Mechanical Engineering, National Taiwan University, Taipei 106, Taiwan
  • Online:2014-09-30
  • Contact: Pei-Chun Lin E-mail:peichunlin@ntu.edu.tw

摘要:

Inspired by kangaroo’s locomotion, we report on developing a kangaroo-style hopping robot. Unlike bipeds, quadrupeds, or hexapods which alternate the legs for forward locomotion, the kangaroo uses both legs synchronously and generates the forward locomotion by continuous hopping behavior, and the tail actively balances the unwanted angular momentum generated by the leg motion. In this work, we generate the Center of Mass (CoM) locomotion of the robot based on the reduced-order Rolling Spring Loaded Inverted Pendulum (R-SLIP) model, for matching the dynamic behavior of the empirical robot legs. In order to compensate the possible body pitch variation, the robot is equipped with an active tail for pitch variation compensation, emulating the balance mechanism of a kangaroo. The robot is empirically built, and various design issues and strategies are addressed. Finally, the experimental evaluation is executed to validate the performance of the kangaroo-style robot with hopping locomotion.

关键词: legged robot, kangaroo, hopping, SLIP, tail

Abstract:

Inspired by kangaroo’s locomotion, we report on developing a kangaroo-style hopping robot. Unlike bipeds, quadrupeds, or hexapods which alternate the legs for forward locomotion, the kangaroo uses both legs synchronously and generates the forward locomotion by continuous hopping behavior, and the tail actively balances the unwanted angular momentum generated by the leg motion. In this work, we generate the Center of Mass (CoM) locomotion of the robot based on the reduced-order Rolling Spring Loaded Inverted Pendulum (R-SLIP) model, for matching the dynamic behavior of the empirical robot legs. In order to compensate the possible body pitch variation, the robot is equipped with an active tail for pitch variation compensation, emulating the balance mechanism of a kangaroo. The robot is empirically built, and various design issues and strategies are addressed. Finally, the experimental evaluation is executed to validate the performance of the kangaroo-style robot with hopping locomotion.

Key words: legged robot, kangaroo, hopping, SLIP, tail