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A parallel type decomposition scheme for quasi-linear abstract hyperbolic equation

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Published/Copyright: July 22, 2022
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Georgian Mathematical Journal
From the journal Georgian Mathematical Journal Volume 29 Issue 6

Abstract

The Cauchy problem for an abstract hyperbolic equation with the Lipschitz continuous operator is considered in the Hilbert space. The operator corresponding to the elliptic part of the equation is the sum of operators A 1 , A 2 , , A m . Each summand is a self-adjoint and positive definite operator. A parallel type decomposition scheme for an approximate solution of the stated problem is constructed. The main idea of the scheme is that on each local interval the classical difference problems are solved in parallel (independently from each other) with the operators A 1 , A 2 , , A m . The weighted average of the obtained solutions is announced as an approximate solution at the right end of the local interval. The convergence of the proposed scheme is proved and the approximate solution error is estimated, as well as the error of the difference analogue for the first-order derivative for the case when the initial problem data satisfy the natural sufficient conditions for solution existence.

Keywords: Decomposition scheme; abstract hyperbolic equation; operator splitting; Cauchy problem; parallel algorithm
MSC 2010: 65M12; 65M15; 65M55; 49M27

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Received: 2022-01-05
Accepted: 2022-02-14
Published Online: 2022-07-22
Published in Print: 2022-12-01

© 2022 Walter de Gruyter GmbH, Berlin/Boston

Articles in the same Issue

  1. Frontmatter
  2. On the Hölder continuity of ring Q-homeomorphisms
  3. New regularity results for the heat equation and application to non-homogeneous Burgers equation
  4. Maximum inequalities in rearrangements of orthogonal series
  5. A parallel type decomposition scheme for quasi-linear abstract hyperbolic equation
  6. Reversible ring property via idempotent elements
  7. Infinitely many solutions for perturbed Λγ-Laplace equations
  8. On an alternative approach for mixed boundary value problems for the Laplace equation
  9. Split monotone variational inclusion problem involving Cayley operators
  10. Duals and approximate duals of von Neumann–Schatten p-frames
  11. Properties of general Fourier coefficients of differentiable functions
  12. On linear spline algorithms of computerized tomography in the space of n-orbits
  13. Barbashin type characterizations for the uniform polynomial stability and instability of evolution families
https://doi.org/10.1515/gmj-2022-2176
Keywords for this article
Decomposition scheme; abstract hyperbolic equation; operator splitting; Cauchy problem; parallel algorithm

Articles in the same Issue

  1. Frontmatter
  2. On the Hölder continuity of ring Q-homeomorphisms
  3. New regularity results for the heat equation and application to non-homogeneous Burgers equation
  4. Maximum inequalities in rearrangements of orthogonal series
  5. A parallel type decomposition scheme for quasi-linear abstract hyperbolic equation
  6. Reversible ring property via idempotent elements
  7. Infinitely many solutions for perturbed Λγ-Laplace equations
  8. On an alternative approach for mixed boundary value problems for the Laplace equation
  9. Split monotone variational inclusion problem involving Cayley operators
  10. Duals and approximate duals of von Neumann–Schatten p-frames
  11. Properties of general Fourier coefficients of differentiable functions
  12. On linear spline algorithms of computerized tomography in the space of n-orbits
  13. Barbashin type characterizations for the uniform polynomial stability and instability of evolution families
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