一类双曲型微分方程边界形状辨识的反问题

Int. J. Math. Math. Sci. Pub Date : 2021-10-18 DOI:10.1155/2021/1716027

F. Ndiaye, I. Ly

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引用次数: 1

摘要

在本文中，我们感兴趣的是确定未知部分∂Ω的逆问题，在一个均匀Lipschitzian域Ω中包含的边界Γ 0N从∂N v在合适部分的法向导数的测量中得到其边界为Γ 0，v是波动方程∂t t v的解X t - Δ v X，T + p x v x = 0在Ω × 0, T和给定的Dirichlet边界数据。我们使用形状优化工具来检索∂Ω的边界部分Γ。从必要条件出发，我们估计了一个拉格朗日乘子k Ω，它在定义域上通过求导得到。利用双曲型方程的极大原理理论，在几何假设条件下，证明了该反问题的唯一性结果。利普希茨稳定性是通过增加系统的能量来建立的。一些数值模拟说明了最优形状。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Inverse Problem Related to Boundary Shape Identification for a Hyperbolic Differential Equation

In this paper, we are interested in the inverse problem of the determination of the unknown part

\partial Ω, Γ_{0}

of the boundary of a uniformly Lipschitzian domain

Ω

included in

ℝ^{N}

from the measurement of the normal derivative

\partial_{n} v

on suitable part

Γ_{0}

of its boundary, where

v

is the solution of the wave equation

\partial_{t t} v (x, t) - Δ v (x, t) + p (x) v (x) = 0

Ω \times (0, T)

and given Dirichlet boundary data. We use shape optimization tools to retrieve the boundary part

Γ

\partial Ω

. From necessary conditions, we estimate a Lagrange multiplier

k (Ω)

which appears by derivation with respect to the domain. By maximum principle theory for hyperbolic equations and under geometrical assumptions, we prove a uniqueness result of our inverse problem. The Lipschitz stability is established by increasing of the energy of the system. Some numerical simulations are made to illustrate the optimal shape.

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Int. J. Math. Math. Sci.

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