Litcius/Paper detail

Automated Routing of Muscle Fibers for Soft Robots

Guirec Maloisel, Espen Knoop, Christian Schumacher, Moritz Bächer

2021IEEE Transactions on Robotics31 citationsDOI

Abstract

This article introduces a computational approach for routing thin artificial muscle actuators through hyperelastic soft robots, in order to achieve a desired deformation behavior. Provided with a robot design and a set of example deformations, we continuously co-optimize the routing of actuators, and their actuation, to approximate example deformations as closely as possible. We introduce a data-driven model for McKibben muscles, modeling their contraction behavior when embedded in a silicone elastomer matrix. To enable the automated routing, a differentiable hyperelastic material simulation is presented. Because standard finite elements are not differentiable at element boundaries, we implement a moving least squares formulation, making the deformation gradient twice differentiable. Our robots are fabricated in a two-step molding process, with the complex mold design steps automated. While most soft robotic designs utilize bending, we study the use of our technique in approximating twisting deformations on a bar example. To demonstrate the efficacy of our technique in soft robotic design, we show a continuum robot, a tentacle, and a four-legged walking robot.

Topics & Concepts

RobotHyperelastic materialActuatorSoft roboticsFinite element methodDifferentiable functionArtificial muscleComputer scienceControl engineeringMechanical engineeringEngineeringArtificial intelligenceStructural engineeringMathematicsMathematical analysisSoft Robotics and ApplicationsRobot Manipulation and LearningAdvanced Materials and Mechanics
Automated Routing of Muscle Fibers for Soft Robots | Litcius