Litcius/Paper detail

Impact Invariant Control with Applications to Bipedal Locomotion

William Yang, Michael Posa

20212021 IEEE/RSJ International Conference on Intelligent Robots and Systems (IROS)27 citationsDOIOpen Access PDF

Abstract

When legged robots impact their environment, they undergo large changes in their velocities in a small amount of time. Measuring and applying feedback to these velocities is challenging, and is further complicated due to uncertainty in the impact model and impact timing. This work proposes a general framework for adapting feedback control during impact by projecting the control objectives to a subspace that is invariant to the impact event. The resultant controller is robust to uncertainties in the impact event while maintaining maximum control authority over the impact invariant subspace. We demonstrate the utility of the projection on a walking controller for a planar five-link-biped and on a jumping controller for a compliant 3D bipedal robot, Cassie. The effectiveness of our method is shown to translate well on hardware.

Topics & Concepts

Control theory (sociology)Invariant (physics)Computer scienceController (irrigation)RobotSubspace topologyInvariant subspacePlanarControl engineeringControl (management)Artificial intelligenceEngineeringMathematicsLinear subspaceBiologyGeometryAgronomyComputer graphics (images)Mathematical physicsRobotic Locomotion and ControlSoil Mechanics and Vehicle DynamicsVehicle Dynamics and Control Systems