On Recurrent Reachability for Continuous Linear Dynamical Systems
Abstract
The continuous evolution of a wide variety of systems, including continuous-time Markov chains and linear hybrid automata, can be described in terms of linear differential equations. In this paper we study the decision problem of whether the solution of a system of linear differential equations reaches a target halfspace infinitely often. This recurrent reachability problem can equivalently be formulated as the following Infinite Zeros Problem: does a real-valued function satisfying a given linear differential equation have infinitely many zeros? Our main decidability result is that if the differential equation has order at most , then the Infinite Zeros Problem is decidable. On the other hand, we show that a decision procedure for the Infinite Zeros Problem at order (and above) would entail a major breakthrough in Diophantine Approximation, specifically an algorithm for computing the Lagrange constants of arbitrary real algebraic numbers to arbitrary precision.
Cite
@article{arxiv.1507.03632,
title = {On Recurrent Reachability for Continuous Linear Dynamical Systems},
author = {Ventsislav Chonev and Joel Ouaknine and James Worrell},
journal= {arXiv preprint arXiv:1507.03632},
year = {2016}
}
Comments
Full version of paper at LICS'16