Analysis of Linear Time-Varying & Periodic Systems

Abstract

This thesis applies Floquet theory to analyze linear periodic time-varying (LPTV) systems, represented by a system of ordinary differential equations (ODEs) that depend on a time variable t and have a matrix of coefficients with period T>0. The transition matrix of an LPTV system represented by a square periodic-function matrix A(t)=A(t+T) can be expressed as the product of a square periodic function matrix P(t)=P(t+T) and an exponentiated square matrix of the form Rt, where R is a constant matrix (independent of t). Despite the validity of Floquet theory, it is difficult to find an analytical closed form for the matrices P(t) and R when the transition matrix {\Phi}_A (t,t_0 ) is unknown. In essence, it is difficult to find an analytical solution for an LPTV system (i.e., a closed form for its transition matrix). The research results show that for a given family of periodic matrices A(t), we can compare the powers of {\omega} that multiply the harmonics (i.e., {\omega} is part of the coefficients multiplying the cosine [sine] factors in even [odd] representations or of the exponential factors in complex representations) to determine the matrices P(t) and R. In addition, the results lead to relations between LPTV systems at frequency {\omega} and the associated linear time-invariant system, which is defined by having zero frequency ({\omega}=0).