The Multidimensional Damped Wave Equation: Maximal Weak Solutions for Nonlinear Forcing via Semigroups and Approximation

Joseph W. Jerome*

*Corresponding author for this work

Research output: Contribution to journalArticlepeer-review

Abstract

The damped nonlinear wave equation, also known as the nonlinear telegraph equation, is studied within the framework of semigroups and eigenfunction approximation. The linear semigroup assumes a central role: it is bounded on the domain of its generator for all time (Formula presented.) This permits eigenfunction approximation within the semigroup framework, as a tool for the study of weak solutions. The semigroup convolution formula, known to be rigorous on the generator domain, is extended to the interpretation of weak solution on an arbitrary time interval. A separate approximation theory can be developed by using the invariance of the semigroup on eigenspaces of the Laplacian as the system evolves. For (locally) bounded continuous L 2 forcing, there is a natural derivation of a maximal solution, which can logically include a constraint on the solution as well. Operator forcing allows for the incorporation of concurrent physical processes. A significant feature of the proof in the nonlinear case is verification of successive approximation without standard fixed point analysis.

Original languageEnglish (US)
Pages (from-to)1970-1989
Number of pages20
JournalNumerical Functional Analysis and Optimization
Volume41
Issue number16
DOIs
StatePublished - 2020

Keywords

  • 35L05
  • 35L20
  • 47D03
  • Equation
  • nonlinear damped wave equation
  • operator forcing
  • semigroup
  • telegraph
  • weak solution

ASJC Scopus subject areas

  • Analysis
  • Signal Processing
  • Computer Science Applications
  • Control and Optimization

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