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IKFlow: Generating Diverse Inverse Kinematics Solutions

Barrett Ames, Jeremy Morgan, George Konidaris

2022IEEE Robotics and Automation Letters46 citationsDOI

Abstract

Inverse kinematics—finding joint poses that reach a given Cartesian-space end-effector pose—is a fundamental operation in robotics, since goals and waypoints are typically defined in Cartesian space, but robots must be controlled in joint space. However, existing inverse kinematics solvers return a single solution, in contrast, systems with more than 6 degrees of freedom support infinitely many such solutions, which can be useful in the presence of constraints, pose preferences, or obstacles. We introduce a method that uses a deep neural network to learn to generate a diverse set of samples from the solution space of such kinematic chains. The resulting samples can be generated quickly (2000 solutions in under 10 ms) and accurately (to within 10 millimeters and 2 degrees of an exact solution) and can be rapidly refined by classical methods if necessary.

Topics & Concepts

Inverse kinematicsKinematicsCartesian coordinate systemRoboticsInverseRobotSpace (punctuation)Degrees of freedom (physics and chemistry)Computer scienceArtificial intelligenceForward kinematicsSet (abstract data type)Robot kinematicsMathematicsGeometryPhysicsClassical mechanicsMobile robotOperating systemQuantum mechanicsProgramming languageRobot Manipulation and LearningRobotic Mechanisms and DynamicsRobotic Path Planning Algorithms
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