Hill's Equation with Small Fluctuations: Cycle to Cycle Variations and Stochastic Processes

Abstract

Hill's equations arise in a wide variety of physical problems, and are specified by a natural frequency, a periodic forcing function, and a forcing strength parameter. This classic problem is generalized here in two ways: [A] to Random Hill's equations which allow the forcing strength qk, the oscillation frequency λk, and the period τk of the forcing function to vary from cycle to cycle, and [B] to Stochastic Hill's equations which contain (at least) one additional term that is a stochastic process . This paper considers both random and stochastic Hill's equations with small parameter variations, so that pk=qk-<qk>, k=λk-<λk>, and are all O(ε), where ε<<1. We show that random Hill's equations and stochastic Hill's equations have the same growth rates when the parameter variations pk and k obey certain constraints given in terms of the moments of . For random Hill's equations, the growth rates for the solutions are given by the growth rates of a matrix transformation, under matrix multiplication, where the matrix elements vary from cycle to cycle. Unlike classic Hill's equations where the parameter space (the λ-q plane) displays bands of stable solutions interlaced with bands of unstable solutions, random Hill's equations are generically unstable. We find analytic approximations for the growth rates of the instability; for the regime where Hill's equation is classically stable, and the parameter variations are small, the growth rate γ = O(ε2). Using the relationship between the (k,pk) and the , this result for γ can be used to find growth rates for stochastic Hill's equations.