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Strictly hyperbolic equations with coefficients low-regular in time and smooth in space

  • Massimo Cicognani
  • Daniel Lorenz
Article

Abstract

We consider the Cauchy problem for strictly hyperbolic m-th order partial differential equations with coefficients low-regular in time and smooth in space. It is well-known that the problem is \(L^2\) well-posed in the case of Lipschitz continuous coefficients in time, \(H^s\) well-posed in the case of Log-Lipschitz continuous coefficients in time (with an, in general, finite loss of derivatives) and Gevrey well-posed in the case of Hölder continuous coefficients in time (with an, in general, infinite loss of derivatives). Here, we use moduli of continuity to describe the regularity of the coefficients with respect to time, weight sequences for the characterization of their regularity with respect to space and weight functions to define the solution spaces. We establish sufficient conditions for the well-posedness of the Cauchy problem, that link the modulus of continuity and the weight sequence of the coefficients to the weight function of the solution space. The well-known results for Lipschitz, Log-Lipschitz and Hölder coefficients are recovered.

Keywords

Higher order strictly hyperbolic Cauchy problem Modulus of continuity Loss of derivatives Pseudodifferential operators 

Mathematics Subject Classification

35S05 35L30 47G30 

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Copyright information

© Springer International Publishing 2017

Authors and Affiliations

  1. 1.Dipartimento di MatematicaUniversita di BolognaBolognaItaly
  2. 2.Institute of Applied Analysis, Faculty of Mathematics and Computer ScienceTU Bergakademie FreibergFreibergGermany

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