English

Learning Reduced-Order Soft Robot Controller

Robotics 2023-11-06 v1

Abstract

Deformable robots are notoriously difficult to model or control due to its high-dimensional configuration spaces. Direct trajectory optimization suffers from the curse-of-dimensionality and incurs a high computational cost, while learning-based controller optimization methods are sensitive to hyper-parameter tuning. To overcome these limitations, we hypothesize that high fidelity soft robots can be both simulated and controlled by restricting to low-dimensional spaces. Under such assumption, we propose a two-stage algorithm to identify such simulation- and control-spaces. Our method first identifies the so-called simulation-space that captures the salient deformation modes, to which the robot's governing equation is restricted. We then identify the control-space, to which control signals are restricted. We propose a multi-fidelity Riemannian Bayesian bilevel optimization to identify task-specific control spaces. We show that the dimension of control-space can be less than 1010 for a high-DOF soft robot to accomplish walking and swimming tasks, allowing low-dimensional MPC controllers to be applied to soft robots with tractable computational complexity.

Keywords

Cite

@article{arxiv.2311.01720,
  title  = {Learning Reduced-Order Soft Robot Controller},
  author = {Chen Liang and Xifeng Gao and Kui Wu and Zherong Pan},
  journal= {arXiv preprint arXiv:2311.01720},
  year   = {2023}
}
R2 v1 2026-06-28T13:10:21.184Z