Your search keyword '"Alkattan Hussein"' showing total 2 results

1. Solving of the Inverse Boundary Value Problem for the Heat Conduction Equation in Two Intervals of Time.

Author

Al-Nuaimi, Bashar Talib, Al-Mahdawi, H.K., Albadran, Zainalabideen, Alkattan, Hussein, Abotaleb, Mostafa, and El-kenawy, El-Sayed M.

Subjects

BOUNDARY value problems, HEAT conduction, SEPARATION of variables, HEAT equation, FOURIER transforms

Abstract

The boundary value problem, BVP, for the PDE heat equation is studied and explained in this article. The problem declaration comprises two intervals; the (0, T) is the first interval and labels the heating of the inside burning chamber, and the second (T, ∞) interval defines the normal cooling of the chamber wall when the chamber temperature concurs with the ambient temperature. It is necessary to prove the boundary function of this problem has its place in the space H 1 0 , ∞ in order to successfully apply the Fourier transform method. The applicability of the Fourier transform for time to this problem is verified. The method of projection regularization is used to solve the inverse boundary value problem for the heat equation and to obtain an evaluation for the error between the approximate and the real solution. These results are new and of practical interest as shown in the numerical case study. [ABSTRACT FROM AUTHOR]

Published

2023

2. Multigrid Method for Solving Inverse Problems for Heat Equation.

Author

Al-Mahdawi, Hassan K. Ibrahim, Abotaleb, Mostafa, Alkattan, Hussein, Tareq, Al-Mahdawi Zena, Badr, Amr, and Kadi, Ammar

Subjects

INVERSE problems, ALGEBRAIC equations, INITIAL value problems, MULTIGRID methods (Numerical analysis), INTEGRAL equations, BOUNDARY value problems, HEAT equation

Abstract

In this paper, the inverse problems for the boundary value and initial value in a heat equation are posed and solved. It is well known that those problems are ill posed. The problems are reformulated as integral equations of the first kind by using the separation-of-variables method. The discretization of the integral equation allowed us to reduce the integral equation to a system of linear algebraic equations or a linear operator equation of the first kind on Hilbert spaces. The Landweber-type iterative method was used in order to find an approximation solution. The V-cycle multigrid method is used to obtain more frequent and fast convergence for iteration. The numerical computation examples are presented to verify the accuracy and fast computing of the approximation solution. [ABSTRACT FROM AUTHOR]

Published

2022