Explicit Discrete Solution for Some Optimization Problems and Estimations with Respect to the Exact Solution
Abstract
We consider two steady-state heat conduction systems called, S and Sα, in a multidimensional bounded domain D for the Poisson equation with source energy g. In one system, we impose mixed boundary conditions (temperature b on the boundary 1, heat flux q on 2 and an adiabatic condition on 3). In the other system, the condition on 1 is replaced by a convective heat flux condition with coefficient α. For each of these systems, we consider three associated optimization problems (Pi) and (Piα ), i=1,2,3, where the variable is the source energy g, the heat flux q and the environmental temperature b, respectively. In the particular case where D is a rectangle, the explicit continuous optimization variables and the corresponding state of the systems are known. In the present work, by using a finite difference scheme, we obtain the discrete systems (Sh) and (Shα) and discrete optimization problems (Phi) and (Phi α), i=1,2,3, where h is the space step in the discretization. Explicit discrete solutions are found, and convergence and estimation errors results are proved when h goes to zero and when α goes to infinity. Moreover, some numerical simulations are provided in order to test theoretical results. Finally, we note that the use of a three-point finite-difference approximation for the Neumann or Robin boundary condition at the boundary improves the global order of convergence from O(h) to O(h2).
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