Boundary control problem for a hyperbolic equation loaded along one of its characteristics

Authors

  • A.Kh. Attaev

DOI:

https://doi.org/10.31489/2022m2/49-58

Keywords:

hyperbolic equation, distributed oscillatory system, damping problem, gas/liquid flows, loaded equation, initial conditions, boundary conditions, analogue of the d’Alembert formula, boundary controls, normal distribution, distribution function

Abstract

This paper investigates the unique solvability of the boundary control problem for a one-dimensional wave equation loaded along one of its characteristic curves in terms of a regular solution. The solution method is based on an analogue of the d’Alembert formula constructed for this equation. We point out that the domain of definition for the solution of DE, when the initial and final Cauchy data given on intervals of the same length is a square. The side of the squire is equal to the interval length. The boundary controls are established by the components of an analogue of the d’Alembert formula, which, in turn, are uniquely established by the initial and final Cauchy data. It should be noted that the normalized distribution and centering are employed in the final formulas of sought boundary controls, which is not typical for initial and boundary value problems initiated by equations of hyperbolic type.

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Published

2022-06-30

Issue

Section

MATHEMATICS