Trajectory Generation for Underactuated Soft Robot Manipulators using Discrete Elastic Rod Dynamics
Abstract
Soft robots are well suited for contact-rich tasks due to their compliance, yet this property makes accurate and tractable modeling challenging. Planning motions with dynamically-feasible trajectories requires models that capture arbitrary deformations, remain computationally efficient, and are compatible with underactuation. However, existing approaches balance these properties unevenly: continuum rod models provide physical accuracy but are computationally demanding, while reduced-order approximations improve efficiency at the cost of modeling fidelity. To address this, our work introduces a control-oriented reformulation of Discrete Elastic Rod (DER) dynamics for soft robots, and a method to generate trajectories with these dynamics. The proposed formulation yields a control-affine representation while preserving certain first-principles force-deformation relationships. As a result, the generated trajectories are both dynamically feasible and consistent with the underlying actuation assumptions. We present our trajectory generation framework and validate it experimentally on a pneumatic soft robotic limb. Hardware results demonstrate consistently improved trajectory tracking performance over a constant-curvature-based baseline, particularly under complex actuation conditions.
Keywords
Cite
@article{arxiv.2603.22604,
title = {Trajectory Generation for Underactuated Soft Robot Manipulators using Discrete Elastic Rod Dynamics},
author = {Beibei Liu and Akua K. Dickson and Ran Jing and Andrew P. Sabelhaus},
journal= {arXiv preprint arXiv:2603.22604},
year = {2026}
}