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Computationally-Robust and Efficient Prioritized Whole-Body Controller with Contact Constraints

Donghyun Kim, Joowon Lee, Junhyeok Ahn, Orion Campbell, Hochul Hwang, Luis Sentis

发表年份
2018
引用次数
43

摘要

In this paper, we devise methods for the multiobjective control of humanoid robots, a.k.a.prioritized wholebody controllers, that achieve efficiency and robustness in the algorithmic computations.We use a form of whole-body controllers that is very general via incorporating centroidal momentum dynamics, operational task priorities, contact reaction forces, and internal force constraints.First, we achieve efficiency by solving a quadratic program that only involves the floating base dynamics and the reaction forces.Second, we achieve computational robustness by relaxing task accelerations such that they comply with friction cone constraints.Finally, we incorporate methods for smooth contact transitions to enhance the control of dynamic locomotion behaviors.The proposed methods are demonstrated both in simulation and in real experiments using a passive-ankle bipedal robot.

关键词

Robustness (evolution)Humanoid robotComputer scienceControl theory (sociology)RobotComputationQuadratic equationContact forceQuadratic programmingRobust control

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