Moving Mesh Strategies of Adaptive Methods for Solving Nonlinear Partial Differential Equations

Qinjiao Gao; Shenggang Zhang

doi:10.3390/a9040086

Moving Mesh Strategies of Adaptive Methods for Solving Nonlinear Partial Differential Equations

Algorithms ◽

10.3390/a9040086 ◽

2016 ◽

Vol 9 (4) ◽

pp. 86 ◽

Cited By ~ 6

Author(s):

Qinjiao Gao ◽

Shenggang Zhang

Keyword(s):

Partial Differential Equations ◽

Differential Equations ◽

Nonlinear Partial Differential Equations ◽

Adaptive Methods ◽

Moving Mesh ◽

Partial Differential

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R-Adaptive Multisymplectic and Variational Integrators

Mathematics ◽

10.3390/math7070642 ◽

2019 ◽

Vol 7 (7) ◽

pp. 642 ◽

Cited By ~ 1

Author(s):

Tomasz M. Tyranowski ◽

Mathieu Desbrun

Keyword(s):

Partial Differential Equations ◽

Differential Equations ◽

Adaptive Methods ◽

Adaptation Strategy ◽

Moving Mesh ◽

Partial Differential ◽

Variational Discretization ◽

Adaptive Schemes ◽

Moving Mesh Methods ◽

Methods Numerical

Moving mesh methods (also called r-adaptive methods) are space-adaptive strategies used for the numerical simulation of time-dependent partial differential equations. These methods keep the total number of mesh points fixed during the simulation but redistribute them over time to follow the areas where a higher mesh point density is required. There are a very limited number of moving mesh methods designed for solving field-theoretic partial differential equations, and the numerical analysis of the resulting schemes is challenging. In this paper, we present two ways to construct r-adaptive variational and multisymplectic integrators for (1+1)-dimensional Lagrangian field theories. The first method uses a variational discretization of the physical equations, and the mesh equations are then coupled in a way typical of the existing r-adaptive schemes. The second method treats the mesh points as pseudo-particles and incorporates their dynamics directly into the variational principle. A user-specified adaptation strategy is then enforced through Lagrange multipliers as a constraint on the dynamics of both the physical field and the mesh points. We discuss the advantages and limitations of our methods. Numerical results for the Sine–Gordon equation are also presented.

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Velocity-Based Moving Mesh Methods for Nonlinear Partial Differential Equations

Communications in Computational Physics ◽

10.4208/cicp.201010.040511a ◽

2011 ◽

Vol 10 (3) ◽

pp. 509-576 ◽

Cited By ~ 27

Author(s):

M. J. Baines ◽

M. E. Hubbard ◽

P. K. Jimack

Keyword(s):

Finite Element ◽

Partial Differential Equations ◽

Differential Equations ◽

Nonlinear Partial Differential Equations ◽

Historical Review ◽

Porous Medium Equation ◽

Moving Mesh ◽

Test Problems ◽

Partial Differential ◽

Two Phase

AbstractThis article describes a number of velocity-based moving mesh numerical methods for multidimensional nonlinear time-dependent partial differential equations (PDEs). It consists of a short historical review followed by a detailed description of a recently developed multidimensional moving mesh finite element method based on conservation. Finite element algorithms are derived for both mass-conserving and non mass-conserving problems, and results shown for a number of multidimensional nonlinear test problems, including the second order porous medium equation and the fourth order thin film equation as well as a two-phase problem. Further applications and extensions are referenced.

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Nonlinear Partial Differential Equations and Related Problems of Pade Approximations.

10.21236/ada141519 ◽

1983 ◽

Author(s):

D. V. Chudnovsky ◽

G. V. Chudnovsky

Keyword(s):

Partial Differential Equations ◽

Differential Equations ◽

Nonlinear Partial Differential Equations ◽

Padé Approximations ◽

Partial Differential ◽

Pade Approximations

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Numerical and Analytical Methods in Nonlinear Partial Differential Equations.

10.21236/ada185210 ◽

1987 ◽

Author(s):

Richard E. Ewing

Keyword(s):

Partial Differential Equations ◽

Differential Equations ◽

Analytical Methods ◽

Nonlinear Partial Differential Equations ◽

Partial Differential ◽

Numerical And Analytical Methods

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Formation of Shocks for Nonlinear Partial Differential Equations of First Order

Proceedings of the Fourth International Colloquium on Differential Equations, Plovdiv, Bulgaria, 18–22 August 1993 ◽

10.1515/9783112318874-022 ◽

1994 ◽

pp. 199-204

Keyword(s):

Partial Differential Equations ◽

Differential Equations ◽

Nonlinear Partial Differential Equations ◽

Partial Differential ◽

First Order

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Lyapunov-type inequalities for partial differential equations with 𝑝-Laplacian

Forum Mathematicum ◽

10.1515/forum-2020-0232 ◽

2021 ◽

Vol 0 (0) ◽

Author(s):

Robert Stegliński

Keyword(s):

Partial Differential Equations ◽

Differential Equations ◽

Boundary Conditions ◽

Dirichlet Boundary ◽

Nonlinear Partial Differential Equations ◽

Dirichlet Boundary Conditions ◽

Partial Differential ◽

Linear Partial Differential Equations ◽

Lyapunov Inequalities ◽

Funct Anal

Abstract The aim of this paper is to extend results from [A. Cañada, J. A. Montero and S. Villegas, Lyapunov inequalities for partial differential equations, J. Funct. Anal. 237 (2006), 1, 176–193] about Lyapunov-type inequalities for linear partial differential equations to nonlinear partial differential equations with 𝑝-Laplacian with zero Neumann or Dirichlet boundary conditions.

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Analytical mathematical schemes: Circular rod grounded via transverse Poisson’s effect and extensive wave propagation on the surface of water

Open Physics ◽

10.1515/phys-2020-0163 ◽

2020 ◽

Vol 18 (1) ◽

pp. 545-554

Author(s):

Asghar Ali ◽

Aly R. Seadawy ◽

Dumitru Baleanu

Keyword(s):

Wave Propagation ◽

Partial Differential Equations ◽

Differential Equations ◽

Longitudinal Wave ◽

Symbolic Computation ◽

Boussinesq Equation ◽

Nonlinear Partial Differential Equations ◽

Wave Model ◽

Simple Equation ◽

Partial Differential

AbstractThis article scrutinizes the efficacy of analytical mathematical schemes, improved simple equation and exp(-\text{Ψ}(\xi ))-expansion techniques for solving the well-known nonlinear partial differential equations. A longitudinal wave model is used for the description of the dispersion in the circular rod grounded via transverse Poisson’s effect; similarly, the Boussinesq equation is used for extensive wave propagation on the surface of water. Many other such types of equations are also solved with these techniques. Hence, our methods appear easier and faster via symbolic computation.

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The (G′/G)-expansion method for finding traveling wave solutions of nonlinear partial differential equations in mathematical physics

Journal of Mathematical Physics ◽

10.1063/1.3033750 ◽

2009 ◽

Vol 50 (1) ◽

pp. 013502 ◽

Cited By ~ 156

Author(s):

E. M. E. Zayed ◽

Khaled A. Gepreel

Keyword(s):

Partial Differential Equations ◽

Differential Equations ◽

Traveling Wave ◽

Nonlinear Partial Differential Equations ◽

Traveling Wave Solutions ◽

Expansion Method ◽

Mathematical Physics ◽

Partial Differential ◽

Wave Solutions

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On the solvability of nonlinear partial differential equations of a high order with deviating argument in lowest terms

Russian Mathematics ◽

10.3103/s1066369x16070021 ◽

2016 ◽

Vol 60 (7) ◽

pp. 7-13

Author(s):

O. I. Bzheumikhova ◽

V. N. Lesev

Keyword(s):

Partial Differential Equations ◽

Differential Equations ◽

Nonlinear Partial Differential Equations ◽

High Order ◽

Partial Differential ◽

Deviating Argument

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Entire solutions of first-order nonlinear partial differential equations

Proceedings of the American Mathematical Society ◽

10.1090/s0002-9939-97-03881-1 ◽

1997 ◽

Vol 125 (5) ◽

pp. 1483-1485 ◽

Cited By ~ 14

Author(s):

Jill E. Hemmati

Keyword(s):

Partial Differential Equations ◽

Differential Equations ◽

Nonlinear Partial Differential Equations ◽

Entire Solutions ◽

Partial Differential ◽

First Order

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