Neural Stochastic Contraction Metrics for Learning-based Control and Estimation

Author(s)

Tsukamoto, Hiroyasu; Chung, Soon-Jo; Slotine, Jean-Jacques E

Abstract

We present Neural Stochastic Contraction Metrics (NSCM), a new design framework for provably-stable learning-based control and estimation for a class of stochastic nonlinear systems. It uses a spectrally-normalized deep neural network to construct a contraction metric and its differential Lyapunov function, sampled via simplified convex optimization in the stochastic setting. Spectral normalization constrains the state-derivatives of the metric to be Lipschitz continuous, thereby ensuring exponential boundedness of the mean squared distance of system trajectories under stochastic disturbances. The trained NSCM model allows autonomous systems to approximate optimal stable control and estimation policies in real-time, and outperforms existing nonlinear control and estimation techniques including the state-dependent Riccati equation, iterative LQR, EKF, and the deterministic NCM, as shown in simulation results.

Date issued

2021

URI

https://hdl.handle.net/1721.1/139679

Journal

IEEE Control Systems Letters

Publisher

Institute of Electrical and Electronics Engineers (IEEE)

Citation

Tsukamoto, Hiroyasu, Chung, Soon-Jo and Slotine, Jean-Jacques E. 2021. "Neural Stochastic Contraction Metrics for Learning-based Control and Estimation." IEEE Control Systems Letters, 5 (5).

Version: Author's final manuscript