Abstract
The weighted gradient reproducing kernel collocation method is introduced to recover the heat source described by Poisson’s equation. As it is commonly known that there is no unique solution to the inverse heat source problem, the weak solution based on a priori assumptions is considered herein. In view of the fourth-order partial differential equation (PDE) in the mathematical model, the high-order gradient reproducing kernel approximation is introduced to efficiently untangle the problem without calculating the high-order derivatives of reproducing kernel shape functions. The weights of the weighted collocation method for high-order inverse analysis are first determined. In the benchmark analysis, the unclear illustration in the literature is clarified, and the correct interpretation of numerical results is given particularly. Two mathematical formulations with four examples are provided to demonstrate the viability of the method, including the extreme cases of the limited accessible boundary.
Highlights
Among the inverse heat source problems are the cylindrical source problems, point source problems, and problems with specified source functions
The aforementioned problems are of second order while the inverse source problems are analyzed by solving the fourth-order partial differential equation (PDE) in strong form, which indicates that the computation of the fourth-order derivatives of reproducing kernel shape functions is required
The present study further introduces the weighted high-order gradient reproducing kernel collocation method (G-RKCM) to compute derivatives implicitly and solve inverse heat source problems efficiently and effectively
Summary
Among the inverse heat source problems are the cylindrical source problems, point source problems, and problems with specified source functions. From a practical point of view, seeking weak solutions might be an option To this end, some weak assumptions have been proposed in order to find the so-called weak solutions to inverse source problems. The present study further introduces the weighted high-order gradient reproducing kernel collocation method (G-RKCM) to compute derivatives implicitly and solve inverse heat source problems efficiently and effectively. Other advanced versions of smooth or gradient reproducing kernel collocation methods have shown the efficacy of solving both the second-order and fourth-order partial differential equations with superconvergent rates recently [8,9,10]. Several benchmark problems are provided to demonstrate the viability of the proposed weighted high-order G-RKCM in solving the fourth-order partial differential equations.
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