A stability criterion for the non-linear wave equation with spatial inhomogeneity

TL;DR

This paper establishes a necessary and sufficient stability criterion for non-linear wave equations with spatial inhomogeneity, linking stability to interval lengths and energy, and illustrating bi-stability and instability conditions.

Contribution

It introduces a novel stability criterion based on interval lengths and energy, applicable to wave equations with spatial inhomogeneity, and uses Evans function analysis for stability and instability assessment.

Findings

Existence of multiple stationary fronts including non-monotonic ones.

Stability depends on the length of the middle interval and associated energy.

Evans function helps identify stable and unstable solution branches.

Abstract

In this paper the non-linear wave equation with a spatial inhomogeneity is considered. The inhomogeneity splits the unbounded spatial domain into three or more intervals, on each of which the non-linear wave equation is homogeneous. In such setting, there often exist multiple stationary fronts. In this paper we present a necessary and sufficient stability criterion in terms of the length of the middle interval(s) and the energy associated with the front in these interval(s). To prove this criterion, it is shown that critical points of the length function and zeros of the linearisation have the same order. Furthermore, the Evans function is used to identify the stable branch. The criterion is illustrated with an example which shows the existence of bi-stability: two stable fronts, one of which is non-monotonic. The Evans function also give a sufficient instability criterion in terms of the derivative of the length function.