Floquet multipliers and the stability of periodic linear differential equations: a unified algorithm and its computer realization

TL;DR

This paper introduces a unified algorithm for computing Floquet multipliers to assess the stability of periodic linear differential equations across discrete, continuous, and hybrid systems, along with a computer implementation.

Contribution

It provides explicit formulas for Floquet multipliers and a computer program for stability analysis of second-order systems on various time scales, unifying and extending prior methods.

Findings

Explicit expressions for Floquet multipliers derived.

Algorithm applicable to discrete, continuous, and hybrid systems.

Computer program accurately determines system stability.

Abstract

Floquet multipliers (characteristic multipliers) play significant role in the stability of the periodic equations. Based on the iterative method, we provide a unified algorithm to compute the Floquet multipliers (characteristic multipliers) and determine the stability of the periodic linear differential equations on time scales unifying discrete, continuous, and hybrid dynamics. Our approach is based on calculating the value of A and B (see Theorem 3.1), which are the sum and product of all Floquet multipliers (characteristic multipliers) of the system, respectively. We obtain an explicit expression of A (see Theorem 4.1) by the method of variation and approximation theory and an explicit expression of B by Liouville's formula. Furthermore, a computer program is designed to realize our algorithm. Specifically, you can determine the stability of a second order periodic linear system, whether they are discrete, continuous or hybrid, as long as you enter the program codes associated with the parameters of the equation. In fact, few literatures have dealt with the algorithm to compute the Floquet multipliers, not mention to design the program for its computer realization. Our algorithm gives the explicit expressions of all Floquet multipliers and our computer program is based on the approximations of these explicit expressions. In particular, on an arbitrary discrete periodic time scale, we can do a finite number of calculations to get the explicit value of Floquet multipliers (see Theorem 4.2). Therefore, for any discrete periodic system, we can accurately determine the stability of the system even without computer! Finally, in Section 6, several examples are presented to illustrate the effectiveness of our algorithm.