Litcius/Paper detail

RIDM: Reinforced Inverse Dynamics Modeling for Learning from a Single Observed Demonstration

Brahma S. Pavse, Faraz Torabi, Josiah P. Hanna, Garrett Warnell, Peter Stone

2020IEEE Robotics and Automation Letters11 citationsDOIOpen Access PDF

Abstract

Augmenting reinforcement learning with imitation learning is often hailed as a method by which to improve upon learning from scratch. However, most existing methods for integrating these two techniques are subject to several strong assumptions-chief among them that information about demonstrator actions is available. In this letter, we investigate the extent to which this assumption is necessary by introducing and evaluating reinforced inverse dynamics modeling (RIDM), a novel paradigm for combining imitation from observation (IfO) and reinforcement learning with no dependence on demonstrator action information. Moreover, RIDM requires only a single demonstration trajectory and is able to operate directly on raw (unaugmented) state features. We find experimentally that RIDM performs favorably compared to a baseline approach for several tasks in simulation, as well as for tasks on a real UR5 robot arm.

Topics & Concepts

Computer scienceReinforcement learningTrajectoryImitationInverse dynamicsScratchArtificial intelligenceInverseBaseline (sea)Dynamics (music)Action (physics)RobotMachine learningHuman–computer interactionMathematicsProgramming languageGeologyGeometryAcousticsAstronomyPhysicsSocial psychologyOceanographyKinematicsClassical mechanicsPsychologyQuantum mechanicsReinforcement Learning in RoboticsRobot Manipulation and LearningModel Reduction and Neural Networks