Litcius/Paper detail

Position and Orientation Control for Hyperelastic Multisegment Continuum Robots

Jialei Shi, Sara-Adela Abad, Jian S. Dai, Helge Würdemann

2024IEEE/ASME Transactions on Mechatronics26 citationsDOIOpen Access PDF

Abstract

Elastomer-based soft-continuum robots with an extensible backbone exhibit high flexibility. These manipulators might show nonlinear kinematic behaviors due to, for example, the material hyperelasticity and means of actuation. Formulating a reliable kinematic model for an effective inverse kinematics control strategy is challenging, but is paramount for allowing effective manoeuvrability and controllability. In this article, we devise a kinematic modeling and control method for pneumatic-driven soft-continuum robots (up to 100% elongation ratio). The method is based on the Cosserat rod model including a pressure-dependent dynamic modulus. The kinematic model and control strategy are then expressed as nonlinear least-squares optimization problems. Hence, various inverse kinematics control modes can be achieved for a multisegment robot, e.g., tip position and orientation control of the overall robot or tip position control of each segment. Simulations and experiments are both conducted to validate the proposed method. The results highlight the high fidelity of the modeling technique and the effectiveness of the proposed inverse kinematics controller. In particular, the modeling and trajectory control errors for a two-segment robot are smaller than 4.5 mm, i.e., 5% of the robot's overall length.

Topics & Concepts

KinematicsControl theory (sociology)Inverse kinematicsControllabilityHyperelastic materialRobotNonlinear systemRobot kinematicsController (irrigation)Computer scienceControl engineeringEngineeringMathematicsPhysicsArtificial intelligenceMobile robotClassical mechanicsControl (management)BiologyQuantum mechanicsApplied mathematicsAgronomySoft Robotics and ApplicationsElasticity and Material ModelingCellular Mechanics and Interactions