The influence of oscillations on energy estimates for damped wave models with time-dependent propagation speed and dissipation

Abstract

The aim of this paper is to derive higher order energy estimates for solutions to the Cauchy problem for damped wave models with time-dependent propagation speed and dissipation. The model of interest is equation* utt-λ2(t)ω2(t) u +(t)ω(t)ut=0, u(0,x)=u0(x), \,\, ut(0,x)=u1(x). equation* The coefficients λ=λ(t) and =(t) are shape functions and ω=ω(t) is an oscillating function. If ω(t)1 and (t)ut is an "effective" dissipation term, then L2-L2 energy estimates are proved in [2]. In contrast, the main goal of the present paper is to generalize the previous results to coefficients including an oscillating function in the time-dependent coefficients. We will explain how the interplay between the shape functions and oscillating behavior of the coefficient will influence energy estimates.