集成质心动力学的双足机器人位置/力混合稳定控制

Felix Sygulla, Robert Wittmann, Philipp Seiwald, Arne-Christoph Hildebrandt, Daniel Wahrmann, D. Rixen
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引用次数: 9

摘要

在地面高度变化较大的不平坦地形中行走仍然是仿人机器人行走稳定性的主要挑战。在这种情况下,平衡双足动物的一种常见方法是控制脚下的地面反作用力。然而,在现有的直接力控制方案中,没有考虑质心的动力学。在这项工作中,我们提出了一种力控制方法,通过加速质心来实现接触力,并将其直接集成到我们的位置/力混合控制方案中。为此,我们首先介绍了任务空间中接触模型的解析公式。我们用我们的人形机器人LOLA在模拟和现实世界的实验中评估了我们的方法的性能。对于地面高度变化5.5 cm的后期接触实验,质心动力学积分表明上体倾角有较大的减小。通过在力控制器中使用系统的质心动力学,可以有效地补偿沿欠驱动自由度的不良运动。我们认为我们的方法是开发更复杂的人形机器人直接力控制概念的起点。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Hybrid position/force control for biped robot stabilization with integrated center of mass dynamics
Traversing uneven terrain with unexpected changes in ground height still poses a major challenge to walking stabilization of humanoid robots. A common approach to balance a biped in such situations is the control of the ground reaction forces at the feet. However, the dynamics of the center of mass is not considered in existing solutions for this direct force control scheme. In this work, we present a force control method to realize contact forces by accelerating the center of mass, which is directly integrated into our hybrid position/force control scheme. For this, we first introduce an analytical formulation for a contact model in task-space. We evaluate the performance of our approach in simulation and real-world experiments with our humanoid robot LOLA. The integration of center of mass dynamics shows great reduction of upper-body inclination angles for a late contact experiment with 5.5 cm change in ground height. We found that by using the system's center of mass dynamics in the force controller, undesired movements along the under-actuated degrees of freedom can be compensated effectively. We consider our approach a starting point for the development of more sophisticated direct force control concepts for humanoid robots.
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