English

Efficient Backward Reachability Using the Minkowski Difference of Constrained Zonotopes

Systems and Control 2022-08-29 v4 Computational Geometry Systems and Control

Abstract

Backward reachability analysis is essential to synthesizing controllers that ensure the correctness of closed-loop systems. This paper is concerned with developing scalable algorithms that under-approximate the backward reachable sets, for discrete-time uncertain linear and nonlinear systems. Our algorithm sequentially linearizes the dynamics, and uses constrained zonotopes for set representation and computation. The main technical ingredient of our algorithm is an efficient way to under-approximate the Minkowski difference between a constrained zonotopic minuend and a zonotopic subtrahend, which consists of all possible values of the uncertainties and the linearization error. This Minkowski difference needs to be represented as a constrained zonotope to enable subsequent computation, but, as we show, it is impossible to find a polynomial-sized representation for it in polynomial time. Our algorithm finds a polynomial-sized under-approximation in polynomial time. We further analyze the conservatism of this under-approximation technique, and show that it is exact under some conditions. Based on the developed Minkowski difference technique, we detail two backward reachable set computation algorithms to control the linearization error and incorporate nonconvex state constraints. Several examples illustrate the effectiveness of our algorithms.

Keywords

Cite

@article{arxiv.2207.04272,
  title  = {Efficient Backward Reachability Using the Minkowski Difference of Constrained Zonotopes},
  author = {Liren Yang and Hang Zhang and Jean-Baptiste Jeannin and Necmiye Ozay},
  journal= {arXiv preprint arXiv:2207.04272},
  year   = {2022}
}

Comments

This article will be presented at the International Conference on Embedded Software (EMSOFT) 2022 and will appear as part of the ESWEEK-TCAD special issue

R2 v1 2026-06-25T00:46:56.294Z