A shift‐adaptive meshfree method for solving a class of initial‐boundary value problems with moving boundaries in one‐dimensional domain

Abstract: A new shift‐adaptive meshfree method for solving a class of time‐dependent partial differential equations (PDEs) in a bounded domain (one‐dimensional domain) with moving boundaries and nonhomogeneous boundary conditions is introduced. The radial basis function (RBF) collocation method is combined with the finite difference scheme, because, unlike with Kansa's method, nonlinear PDEs can be converted to a system of linear equations. The grid‐free property of the RBF method is exploited, and a new adaptive algori… Show more

“…In Tables 2-4 we present an extensive and detailed analysis on the RBF-PUM-FD collocation method, which is also compared with the global RBF-FD method studied in [24]. More precisely, considering four sets of uniform and Halton points and IMQ as local RBF approximant, we report the MAE computed with "optimal" ǫ, the CPU time required to solve the sparse linear system (29) and the CN.…”

“…Then, in Tables 7-10 we compare our RBF-PUM-FD scheme with the RBF-FD method studied in [24]. Therefore, for some sets of uniform and Halton points we show the numerical results obtained by using IMQ and GA as local RBF approximants.…”

“…The target of our numerical analysis is thus two-fold: on the one hand, analyzing the efficiency expressed in terms of CPU times of the RBF-PUM-FD; on the other hand, verifying its accuracy and stability. In addition, we also compare our collocation method with two existing techniques: the RBF-FD method presented in [24] and the RBF-PUM proposed in [43].…”

“…The semi-implicit scheme is somewhere between the explicit and implicit schemes. Although the conclusion as to which type of scheme should be chosen is to consider case by case, usually the implicit scheme is preferred for stiff initial value problems [36,24].…”

“…In this work, we thus have a two-fold scope: first, exhibiting efficiency of our RBF-PUM-FD method in terms of CPU times; then, analyzing its numerical accuracy and stability. Finally, in order to show goodness of our approach, we compare our collocation method with two existing computational techniques: the global RBF-FD method proposed in [24] and the RBF-PUM studied in [43].…”

A RBF partition of unity collocation method based on finite difference for initial–boundary value problems

“…In Tables 2-4 we present an extensive and detailed analysis on the RBF-PUM-FD collocation method, which is also compared with the global RBF-FD method studied in [24]. More precisely, considering four sets of uniform and Halton points and IMQ as local RBF approximant, we report the MAE computed with "optimal" ǫ, the CPU time required to solve the sparse linear system (29) and the CN.…”

“…Then, in Tables 7-10 we compare our RBF-PUM-FD scheme with the RBF-FD method studied in [24]. Therefore, for some sets of uniform and Halton points we show the numerical results obtained by using IMQ and GA as local RBF approximants.…”

“…The target of our numerical analysis is thus two-fold: on the one hand, analyzing the efficiency expressed in terms of CPU times of the RBF-PUM-FD; on the other hand, verifying its accuracy and stability. In addition, we also compare our collocation method with two existing techniques: the RBF-FD method presented in [24] and the RBF-PUM proposed in [43].…”

“…The semi-implicit scheme is somewhere between the explicit and implicit schemes. Although the conclusion as to which type of scheme should be chosen is to consider case by case, usually the implicit scheme is preferred for stiff initial value problems [36,24].…”

“…In this work, we thus have a two-fold scope: first, exhibiting efficiency of our RBF-PUM-FD method in terms of CPU times; then, analyzing its numerical accuracy and stability. Finally, in order to show goodness of our approach, we compare our collocation method with two existing computational techniques: the global RBF-FD method proposed in [24] and the RBF-PUM studied in [43].…”

A RBF partition of unity collocation method based on finite difference for initial–boundary value problems

An RBF-PUM finite difference scheme for forward–backward heat equation

Adaptive residual refinement in an RBF finite difference scheme for 2D time-dependent problems