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LQR-Assisted Whole-Body Control of a Wheeled Bipedal Robot With Kinematic Loops

Victor Klemm, Alessandro Morra, Lionel Gulich, Dominik Mannhart, David Rohr, Mina Kamel, Yvain de Viragh, Roland Siegwart

2020IEEE Robotics and Automation Letters181 citationsDOIOpen Access PDF

Abstract

We present a hierarchical whole-body controller leveraging the full rigid body dynamics of the wheeled bipedal robot Ascento. We derive closed-form expressions for the dynamics of its kinematic loops in a way that readily generalizes to more complex systems. The rolling constraint is incorporated using a compact analytic solution based on rotation matrices. The non-minimum phase balancing dynamics are accounted for by including a linear-quadratic regulator as a motion task. Robustness when driving curves is increased by regulating the lean angle as a function of the zero-moment point. The proposed controller is computationally lightweight and significantly extends the rough-terrain capabilities and robustness of the system, as we demonstrate in several experiments.

Topics & Concepts

Control theory (sociology)KinematicsRobustness (evolution)Linear-quadratic regulatorComputer scienceZero moment pointRobotControl engineeringEngineeringHumanoid robotArtificial intelligenceControl (management)PhysicsClassical mechanicsChemistryGeneBiochemistryRobotic Locomotion and ControlControl and Dynamics of Mobile RobotsBiomimetic flight and propulsion mechanisms
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