We propose a new non-parametric framework for learning incrementally stable dynamical systems x' = f(x) from a set of sampled trajectories. We construct a rich family of smooth vector fields induced by certain classes of matrix-valued kernels, whose equilibria are placed exactly at a desired set of locations and whose local contraction and curvature properties at various points can be explicitly controlled using convex optimization. With curl-free kernels, our framework may also be viewed as a mechanism to learn potential fields and gradient flows. We develop large-scale techniques using randomized kernel approximations in this context. We demonstrate our approach, called contracting vector fields (CVF), on imitation learning tasks involving complex point-to-point human handwriting motions.
@article{arxiv.1804.04878,
title = {Learning Contracting Vector Fields For Stable Imitation Learning},
author = {Vikas Sindhwani and Stephen Tu and Mohi Khansari},
journal= {arXiv preprint arXiv:1804.04878},
year = {2018}
}