English

Data-Driven Soft Robot Control via Adiabatic Spectral Submanifolds

Robotics 2025-10-28 v2 Systems and Control Systems and Control Pattern Formation and Solitons

Abstract

The mechanical complexity of soft robots creates significant challenges for their model-based control. Specifically, linear data-driven models have struggled to control soft robots on complex, spatially extended paths that explore regions with significant nonlinear behavior. To account for these nonlinearities, we develop here a model-predictive control strategy based on the recent theory of adiabatic spectral submanifolds (aSSMs). This theory is applicable because the internal vibrations of heavily overdamped robots decay at a speed that is much faster than the desired speed of the robot along its intended path. In that case, low-dimensional attracting invariant manifolds (aSSMs) emanate from the path and carry the dominant dynamics of the robot. Aided by this recent theory, we devise an aSSM-based model-predictive control scheme purely from data. We demonstrate our data-driven model's effectiveness in tracking dynamic trajectories across diverse tasks, validated on a high-fidelity, high-dimensional finite-element model of a soft trunk robot and a Cosserat rod-based elastic soft arm. Notably, we find that five- or six-dimensional aSSM-reduced models outperform the tracking performance of other data-driven modeling methods by a factor up to 1010 across all closed-loop control tasks.

Keywords

Cite

@article{arxiv.2503.10919,
  title  = {Data-Driven Soft Robot Control via Adiabatic Spectral Submanifolds},
  author = {Roshan S. Kaundinya and John Irvin Alora and Jonas G. Matt and Luis A. Pabon and Marco Pavone and George Haller},
  journal= {arXiv preprint arXiv:2503.10919},
  year   = {2025}
}

Comments

41 pages, 24 figures

R2 v1 2026-06-28T22:19:53.430Z