English

An Input-to-State Stability Perspective on Robust Locomotion

Robotics 2023-06-12 v2 Systems and Control Systems and Control

Abstract

Uneven terrain necessarily transforms periodic walking into a non-periodic motion. As such, traditional stability analysis tools no longer adequately capture the ability of a bipedal robot to locomote in the presence of such disturbances. This motivates the need for analytical tools aimed at generalized notions of stability -- robustness. Towards this, we propose a novel definition of robustness, termed \emph{δ\delta-robustness}, to characterize the domain on which a nominal periodic orbit remains stable despite uncertain terrain. This definition is derived by treating perturbations in ground height as disturbances in the context of the input-to-state-stability (ISS) of the extended Poincar\'{e} map associated with a periodic orbit. The main theoretic result is the formulation of robust Lyapunov functions that certify δ\delta-robustness of periodic orbits. This yields an optimization framework for verifying δ\delta-robustness, which is demonstrated in simulation with a bipedal robot walking on uneven terrain.

Keywords

Cite

@article{arxiv.2303.10231,
  title  = {An Input-to-State Stability Perspective on Robust Locomotion},
  author = {Maegan Tucker and Aaron D. Ames},
  journal= {arXiv preprint arXiv:2303.10231},
  year   = {2023}
}

Comments

6 pages

R2 v1 2026-06-28T09:22:06.748Z