Smoothing estimates for non-dispersive equations

Abstract

This paper describes an approach to global smoothing problems for non-dispersive equations based on ideas of comparison principle and canonical transformation established in authors' previous paper, where dispersive equations were treated. For operators a(Dx) of order m satisfying the dispersiveness condition ∇ a()≠0 for =0, the global smoothing estimate \| x-s|Dx|(m-1)/2eita(Dx) (x)\|L2( Rt× Rnx) ≤ C\|\|L2( Rnx) (s>1/2) is well-known, while it is also known to fail for non-dispersive operators. For the case when the dispersiveness breaks, we suggest the estimate in the form \|x-s|∇ a(Dx)|1/2 eit a(Dx)(x)\|L2( Rt× Rnx) ≤ C\|\|L2( Rnx)(s>1/2) which is equivalent to the usual estimate in the dispersive case and is also invariant under canonical transformations for the operator a(Dx). We show that this estimate and its variants do continue to hold for a variety of non-dispersive operators a(Dx), where ∇ a() may become zero on some set. Moreover, other types of such estimates, and the case of time-dependent equations are also discussed.