Related papers: Learning physics-informed simulation models for soft robotic manipulation: A case study with dielectric elastomer actuators

Learning physics-informed simulation models for soft robotic manipulation: A case study with dielectric elastomer actuators

URL: http://arxiv.org/abs/2202.12977v1
Date: Fri, 25 Feb 2022 21:15:05 GMT
Title: Learning physics-informed simulation models for soft robotic manipulation: A case study with dielectric elastomer actuators
Authors: Manu Lahariya and Craig Innes and Chris Develder and Subramanian Ramamoorthy
Abstract summary: Soft actuators offer a safe and adaptable approach to robotic tasks like gentle grasping and dexterous movement. Creating accurate models to control such systems is challenging due to the complex physics of deformable materials. This paper presents a framework that combines the advantages of differentiable simulator and Finite Element Method.
Score: 21.349079159359746
License: http://creativecommons.org/licenses/by/4.0/
Abstract: Soft actuators offer a safe and adaptable approach to robotic tasks like gentle grasping and dexterous movement. Creating accurate models to control such systems, however, is challenging due to the complex physics of deformable materials. Accurate Finite Element Method (FEM) models incur prohibitive computational complexity for closed-loop use. Using a differentiable simulator is an attractive alternative, but their applicability to soft actuators and deformable materials remains under-explored. This paper presents a framework that combines the advantages of both. We learn a differentiable model consisting of a material properties neural network and an analytical dynamics model of the remainder of the manipulation task. This physics-informed model is trained using data generated from FEM and can be used for closed-loop control and inference. We evaluate our framework on a dielectric elastomer actuator (DEA) coin-pulling task. We simulate DEA coin pulling in FEM, and design experiments to evaluate the physics-informed model for simulation, control, and inference. Our model attains < 5% simulation error compared to FEM, and we use it as the basis for an MPC controller that outperforms (i.e., requires fewer iterations to converge) a model-free actor-critic policy, a heuristic policy, and a PD controller.

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