Abstract

This paper proposes an online gain adaptation approach to enhance the robustness of whole-body control (WBC) framework for legged robots under unknown external force disturbances. Without properly accounting for external forces, the closed-loop control system incorporating WBC may become unstable, and therefore the desired task goals may not be achievable. To study the effects of external disturbances, we analyze the behavior of our current WBC framework via the use of both full-body and centroidal dynamics. In turn, we propose a way to adapt feedback gains for stabilizing the controlled system automatically. Based on model approximations and stability theory, we propose three conditions to ensure that the adjusted gains are suitable for stabilizing a robot under WBC. The proposed approach has four contributions. We make it possible to estimate the unknown disturbances without force/torque sensors. We then compute adaptive gains based on theoretic stability analysis incorporating the unknown forces at the joint actuation level. We demonstrate that the proposed method reduces task tracking errors under the effect of external forces on the robot. In addition, the proposed method is easy-to-use without further modifications of the controllers and task specifications. The resulting gain adaptation process is able to run in real-time. Finally, we verify the effectiveness of our method both in simulations and experiments using the bipedal robot Draco2 and the humanoid robot Valkyrie.

Highlights

  • Stability analysis for efficient whole-body control (WBC) of humanoid robots is important to execute robustly multiple tasks in bipedal and humanoid robots

  • This paper proposes an online gain adaptation approach to enhance the robustness of whole-body control (WBC) framework for legged robots under unknown external force disturbances

  • This paper proposes an online gain adaptation method based on stability analysis of the closed-loop robotic system via WBC

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Summary

INTRODUCTION

Stability analysis for efficient whole-body control (WBC) of humanoid robots is important to execute robustly multiple tasks in bipedal and humanoid robots. Most WBC approaches face difficulty ensuring the stability at the closed loop systems due to intricate control structures. For this reason, bipedal and humanoid robot stability is frequently studies in task-space, based on constant feedback gains. Bipedal and humanoid robot stability is frequently studies in task-space, based on constant feedback gains These feedback gains defined a priori might be inappropriate to track the planned motions robustly and stabilize the robot’s behaviors under unknown external disturbances. This paper proposes an online gain adaptation method based on stability analysis of the closed-loop robotic system via WBC. Our online gain adaptation approach utilizes three methods: 1) a WBC controller, dubbed Whole-Body Locomotion Controller (WBLC), 2) a Centroidal dynamic model, and 3) various approximation techniques

Whole-Body Control
Robots With External Disturbances
Contributions
QP-Based Whole-Body Locomotion
Closed-Loop Analysis Without External Perturbations
PROPOSED GAIN ADAPTATION METHOD
Closed-Loop Behavior With External Forces
The Proposed Gain Adaptation
SIMULATIONS AND EXPERIMENTS
Draco2 Simulations
Pushing Force While Swinging
Draco2 Experiments
Valkyrie Simulations
CONCLUSION
Findings
DATA AVAILABILITY STATEMENT

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