English

Composable Geometric Motion Policies using Multi-Task Pullback Bundle Dynamical Systems

Robotics 2021-03-26 v2

Abstract

Despite decades of work in fast reactive planning and control, challenges remain in developing reactive motion policies on non-Euclidean manifolds and enforcing constraints while avoiding undesirable potential function local minima. This work presents a principled method for designing and fusing desired robot task behaviors into a stable robot motion policy, leveraging the geometric structure of non-Euclidean manifolds, which are prevalent in robot configuration and task spaces. Our Pullback Bundle Dynamical Systems (PBDS) framework drives desired task behaviors and prioritizes tasks using separate position-dependent and position/velocity-dependent Riemannian metrics, respectively, thus simplifying individual task design and modular composition of tasks. For enforcing constraints, we provide a class of metric-based tasks, eliminating local minima by imposing non-conflicting potential functions only for goal region attraction. We also provide a geometric optimization problem for combining tasks inspired by Riemannian Motion Policies (RMPs) that reduces to a simple least-squares problem, and we show that our approach is geometrically well-defined. We demonstrate the PBDS framework on the sphere S2\mathbb S^2 and at 300-500 Hz on a manipulator arm, and we provide task design guidance and an open-source Julia library implementation. Overall, this work presents a fast, easy-to-use framework for generating motion policies without unwanted potential function local minima on general manifolds.

Keywords

Cite

@article{arxiv.2101.01297,
  title  = {Composable Geometric Motion Policies using Multi-Task Pullback Bundle Dynamical Systems},
  author = {Andrew Bylard and Riccardo Bonalli and Marco Pavone},
  journal= {arXiv preprint arXiv:2101.01297},
  year   = {2021}
}
R2 v1 2026-06-23T21:46:44.451Z