Localized collocation schemes and their applications

Localized collocation schemes and their applications

This paper presents a summary of various localized collocation schemes and their engineering applications. The basic concepts of localized collocation methods (LCMs) are first introduced, such as approximation theory, semianalytical collocation methods and localization strategies. Based on these bas...

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Bibliographic Details
Published in:Acta mechanica Sinica Vol. 38; no. 7
Main Authors: Fu, Zhuojia, Tang, Zhuochao, Xi, Qiang, Liu, Qingguo, Gu, Yan, Wang, Fajie
Format: Journal Article
Language:English
Published: Beijing The Chinese Society of Theoretical and Applied Mechanics; Institute of Mechanics, Chinese Academy of Sciences 01-07-2022
Springer Nature B.V
Edition:English ed.
Subjects:
Boundary value problems
Burgers equation
Classical and Continuum Physics
Collocation methods
Computational Intelligence
Conduction heating
Conductive heat transfer
Electrocardiography
Engineering
Engineering Fluid Dynamics
Finite difference method
Fourier transforms
Invited Review
Partial differential equations
Radial basis function
Reciprocity
Theoretical and Applied Mechanics
Time dependence
Trefftz method
Two dimensional analysis
Wave propagation
Semianalytical
Computational mechanics
Localization
Collocation method
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Summary:This paper presents a summary of various localized collocation schemes and their engineering applications. The basic concepts of localized collocation methods (LCMs) are first introduced, such as approximation theory, semianalytical collocation methods and localization strategies. Based on these basic concepts, five different formulations of localized collocation methods are introduced, including the localized radial basis function collocation method (LRBFCM) and the generalized finite difference method (GFDM), the localized method of fundamental solutions (LMFS), the localized radial Trefftz collocation method (LRTCM), and the localized collocation Trefftz method (LCTM). Then, several additional schemes, such as the generalized reciprocity method, Laplace and Fourier transformations, and Krylov deferred correction, are introduced to enable the application of the LCM to large-scale engineering and scientific computing for solving inhomogeneous, nonisotropic and time-dependent partial differential equations. Several typical benchmark examples are presented to show the recent developments and applications on the LCM solution of some selected boundary value problems, such as numerical wave flume, potential-based inverse electrocardiography, wave propagation analysis and 2D phononic crystals, elasticity and in-plane crack problems, heat conduction problems in heterogeneous material and nonlinear time-dependent Burgers’ equations. Finally, some conclusions and outlooks of the LCMs are summarized.
ISSN:0567-7718
1614-3116
DOI:10.1007/s10409-022-22167-x