Abstract
This work is devoted to finding an estimate of the convergence rate of an algorithm for numerically solving the optimal control problem for the three-dimensional heat equation. An important aspect of the work is not only the establishment of convergence of solutions of a sequence of discrete problems to the solution of the original differential problem, but the determination of the order of convergence, which plays a very important role in applications. The paper uses the discretization method of the differential problem and the method of integral estimates. The reduction of a differential multidimensional mixed problem to a difference one is based on the approximation of the desired solution and its derivatives by difference expressions, for which the error of such an approximation is known. The idea of using integral estimates is typical for such problems, but in the multidimensional case significant technical difficulties arise. To estimate errors, we used multidimensional analogues of the integration formula by parts, Friedrichs and Poincare inequalities. The technique used in this work can be applied under some additional assumptions, and for nonlinear multidimensional mixed problems of parabolic type. To find a numerical solution, the variable direction method is used for the difference problem of a parabolic type equation. The resulting algorithm is implemented using program code written in the Python 3.7 programming language.
Highlights
The heat equation is used to find the dependence of the temperature of the medium on the spatial coordinates and time, for given coefficients of heat capacity and heat conductivity
The aim of this work is to estimate the approximation of a finite-difference analogue for the heat equation of three spatial variables
The problem of determining the approximation order of the optimal control problem for the spatial process of heat conduction is considered in the paper
Summary
The heat equation is used to find the dependence of the temperature of the medium on the spatial coordinates and time, for given coefficients of heat capacity and heat conductivity. This is a second order partial differential equation, which is a parabolic type equation. Since differential problems of a continuous nature cannot be programmed due to the limited capabilities of computer technology, such problems, by discretizing them, reduce to similar difference problems. Such a transition is carried out using difference schemes
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