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Optimal control for whole-body motion generation using center-of-mass dynamics for predefined multi-contact configurations

Manuel Kudruss, M. Naveau, Olivier Stasse, Nicolas Mansard, Christian Kirches, Philippe Souères, Katja Mombaur

Year
2015
Citations
42

Abstract

Multi-contact motion generation is an important problem in humanoid robotics because it generalizes bipedal locomotion and thus expands the functional range of humanoid robots. In this paper, we propose a complete solution to compute a fully-dynamic multi-contact motion of a humanoid robot. We decompose the motion generation by computing first a dynamically-consistent trajectory of the center of mass of the robot and finding then the whole-body movement following this trajectory. A simplified dynamic model of the humanoid is used to find optimal contact forces as well as a kinematic feasible center-of-mass trajectory from a predefined series of contacts. We demonstrate the capabilities of the approach by making the real humanoid robot platform HRP-2 climb stairs with the use of a handrail. The experimental study also shows that utilization of the handrail lowers the power consumption of the robot by 25% compared to a motion, where only the feet are used.

Keywords

Humanoid robotTrajectoryKinematicsClimbComputer scienceMotion (physics)RobotCenter of mass (relativistic)SimulationRobot kinematics

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