Litcius/Paper detail

Contact-Implicit Trajectory Optimization Using an Analytically Solvable Contact Model for Locomotion on Variable Ground

Iordanis Chatzinikolaidis, Yangwei You, Zhibin Li

2020IEEE Robotics and Automation Letters31 citationsDOIOpen Access PDF

Abstract

This letter presents a novel contact-implicit trajectory optimization method using an analytically solvable contact model to enable planning of interactions with hard, soft, and slippery environments. Specifically, we propose a novel contact model that can be computed in closed-form, satisfies friction cone constraints and can be embedded into direct trajectory optimization frameworks without complementarity constraints. The closed-form solution decouples the computation of the contact forces from other actuation forces and this property is used to formulate a minimal direct optimization problem expressed with configuration variables only. Our simulation study demonstrates the advantages over the rigid contact model and a trajectory optimization approach based on complementarity constraints. The proposed model enables physics-based optimization for a wide range of interactions with hard, slippery, and soft grounds in a unified manner expressed by two parameters only. By computing trotting and jumping motions for a quadruped robot, the proposed optimization demonstrates the versatility for multi-contact motion planning on surfaces with different physical properties.

Topics & Concepts

Trajectory optimizationComplementarity (molecular biology)TrajectoryLinear complementarity problemComputationRobotOptimization problemMathematical optimizationComputer scienceMotion planningControl theory (sociology)MathematicsOptimal controlPhysicsAlgorithmArtificial intelligenceGeneticsQuantum mechanicsNonlinear systemBiologyAstronomyControl (management)Robotic Locomotion and ControlRobot Manipulation and LearningRobotic Mechanisms and Dynamics