Your search keyword '"Petrov-Galerkin method"' showing total 14 results

1. Analysis of a class of spectral volume methods for linear scalar hyperbolic conservation laws.

Author

Lu, Jianfang, Jiang, Yan, Shu, Chi‐Wang, and Zhang, Mengping

Subjects

*CONSERVATION laws (Physics), *FUNCTION spaces, *GALERKIN methods, *A priori, *POLYNOMIALS

Abstract

In this article, we study the spectral volume (SV) methods for scalar hyperbolic conservation laws with a class of subdivision points under the Petrov–Galerkin framework. Due to the strong connection between the DG method and the SV method with the appropriate choice of the subdivision points, it is natural to analyze the SV method in the Galerkin form and derive the analogous theoretical results as in the DG method. This article considers a class of SV methods, whose subdivision points are the zeros of a specific polynomial with a parameter in it. Properties of the piecewise constant functions under this subdivision, including the orthogonality between the trial solution space and test function space, are provided. With the aid of these properties, we are able to derive the energy stability, optimal a priori error estimates of SV methods with arbitrary high order accuracy. We also study the superconvergence of the numerical solution with the correction function technique, and show the order of superconvergence would be different with different choices of the subdivision points. In the numerical experiments, by choosing different parameters in the SV method, the theoretical findings are confirmed by the numerical results. [ABSTRACT FROM AUTHOR]

Published

2024

2. A Petrov–Galerkin RBF method for diffusion equation on the unit sphere.

Author

Darani, Mohammadreza Ahmadi and Mirzaei, Davoud

Subjects

*HEAT equation, *SPHERICAL functions, *NUMERICAL solutions to equations, *SPHERES, *NUMERICAL integration

Abstract

This paper concerns a numerical solution for the diffusion equation on the unit sphere. The given method is based on the spherical basis function approximation and the Petrov–Galerkin test discretization. The method is meshless because spherical triangulation is not required neither for approximation nor for numerical integration. This feature is achieved through the spherical basis function approximation and the use of local weak forms instead of a global variational formulation. The local Petrov–Galerkin formulation allows to compute the integrals on small independent spherical caps without any dependence on a connected background mesh. Experimental results show the accuracy and the efficiency of the new method. [ABSTRACT FROM AUTHOR]

Published

2020

3. Application of direct meshless local <scp>Petrov–Galerkin</scp> method for numerical solution of stochastic elliptic interface problems

Author

Amirreza Khodadadian, Mostafa Abbaszadeh, Clemens Heitzinger, and Mehdi Dehghan

Subjects

Computational Mathematics, Numerical Analysis, Interface (Java), Applied Mathematics, Petrov–Galerkin method, Applied mathematics, Analysis, Mathematics

Published

2021

4. A Petrov–Galerkin RBF method for diffusion equation on the unit sphere

Author

Mohammadreza Ahmadi Darani and Davoud Mirzaei

Subjects

Unit sphere, Computational Mathematics, Numerical Analysis, Diffusion equation, Applied Mathematics, Mathematical analysis, Petrov–Galerkin method, Meshfree methods, Radial basis function, Analysis, Mathematics

Published

2020

5. Numerical approximation of the generalized regularized long wave equation using Petrov–Galerkin finite element method

Author

Seydi Battal Gazi Karakoç, Samir Kumar Bhowmik, and Nevşehir Hacı Bektaş Veli Üniversitesi/fen-edebiyat fakültesi/matematik bölümü/uygulamalı matematik anabilim dalı

Subjects

Numerical Analysis, GRLW equation, Applied Mathematics, Mathematical analysis, Petrov–Galerkin method, Numerical Analysis (math.NA), Wave equation, Finite element method, Computational Mathematics, Numerical approximation, Petrov–Galerkin, FOS: Mathematics, Cubic b splines, Cubic B-spline, Mathematics - Numerical Analysis, Soliton, Analysis, Mathematics

Abstract

The generalized regularized long wave (GRLW) equation has been developed to model a variety of physical phenomena such as ion-acoustic and magnetohydrodynamic waves in plasma, nonlinear transverse waves in shallow water and phonon packets in nonlinear crystals. This paper aims to develop and analyze a powerful numerical scheme for the nonlinear generalized regularized long wave (GRLW) equation by Petrov--Galerkin method in which the element shape functions are cubic and weight functions are quadratic B-splines. The suggested method is performed to three test problems involving propagation of the single solitary wave, interaction of two solitary waves and evolution of solitons with the Maxwellian initial condition. The variational formulation and semi-discrete Galerkin scheme of the equation are firstly constituted. We estimate accuracy of such a spatial approximation. Then Fourier stability analysis of the linearized scheme shows that it is unconditionally stable. To verify practicality and robustness of the new scheme error norms $L_{2}$, $L_{\infty }$ and three invariants $I_{1},I_{2}$ and $I_{3}$ are calculated. The obtained numerical results are compared with other published results and shown to be precise and effective., 28 pages

Published

2019

6. Inf-sup stability of Petrov-Galerkin immersed finite element methods for one-dimensional elliptic interface problems

Author

Bin Zhang, Haifeng Ji, and Qian Zhang

Subjects

Numerical Analysis, Interface (Java), Applied Mathematics, Mathematical analysis, Petrov–Galerkin method, 010103 numerical & computational mathematics, 01 natural sciences, Stability (probability), Finite element method, 010101 applied mathematics, Computational Mathematics, 0101 mathematics, Analysis, Mathematics

Published

2018

7. A greedy meshless local Petrov-Galerkin methodbased on radial basis functions

Author

Davoud Mirzaei

Subjects

Numerical Analysis, Mathematical optimization, Regularized meshless method, Applied Mathematics, Linear system, Petrov–Galerkin method, 010103 numerical & computational mathematics, Sparse approximation, 01 natural sciences, 010101 applied mathematics, Computational Mathematics, Applied mathematics, Radial basis function, 0101 mathematics, Greedy algorithm, Condition number, Analysis, Mathematics, Numerical partial differential equations

Abstract

The meshless local Petrov–Galerkin (MLPG) method with global radial basis functions (RBF) as trial approximation leads to a full final linear system and a large condition number. This makes MLPG less efficient when the number of data points is increased. We can overcome this drawback if we avoid using more points from the data site than absolutely necessary. In this article, we equip the MLPG method with the greedy sparse approximation technique of (Schaback, Numercail Algorithms 67 (2014), 531–547) and use it for numerical solution of partial differential equations. This scheme uses as few neighbor nodal values as possible and allows to control the consistency error by explicit calculation. Whatever the given RBF is, the final system is sparse and the algorithm is well-conditioned. © 2015 Wiley Periodicals, Inc. Numer Methods Partial Differential Eq 32: 847–861, 2016

Published

2015

8. An ADI Petrov-Galerkin method with quadrature for parabolic problems

Author

Bernard Bialecki, Mahadevan Ganesh, and Kassem Mustapha

Subjects

Numerical Analysis, Laplace transform, Applied Mathematics, Mathematical analysis, Petrov–Galerkin method, Parabolic cylinder function, Mathematics::Numerical Analysis, Quadrature (mathematics), Computational Mathematics, Elliptic operator, Alternating direction implicit method, symbols.namesake, symbols, Gaussian quadrature, Partial derivative, Analysis, Mathematics

Abstract

We propose and analyze a fully discrete Laplace modified alternating direction implicit quadrature Petrov–Galerkin (ADI-QPG) method for solving parabolic initial-boundary value problems on rectangular domains. We prove optimal order convergence results for a restricted class of the associated elliptic operator and demonstrate accuracy of our scheme with numerical experiments for some parabolic problems with variable coefficients.© 2008 Wiley Periodicals, Inc. Numer Methods Partial Differential Eq, 2009

Published

2009

9. A Petrov-Galerkin method with quadrature for semi-linear second-order hyperbolic problems

Author

Kassem Mustapha, Mahadevan Ganesh, and Bernard Bialecki

Subjects

Numerical Analysis, Applied Mathematics, Mathematical analysis, Petrov–Galerkin method, Tanh-sinh quadrature, Mathematics::Numerical Analysis, Quadrature (mathematics), Computational Mathematics, Spline (mathematics), symbols.namesake, Norm (mathematics), symbols, Crank–Nicolson method, Partial derivative, Gaussian quadrature, Analysis, Mathematics

Abstract

We propose and analyze a Crank–Nicolson quadrature Petrov–Galerkin (CNQPG) -spline method for solving semi-linear second-order hyperbolic initial-boundary value problems. We prove second-order convergence in time and optimal order H2 norm convergence in space for the CNQPG scheme that requires only linear algebraic solvers. We demonstrate numerically optimal order Hk, k = 0,1,2, norm convergence of the scheme for some test problems with smooth and nonsmooth nonlinearities. © 2006 Wiley Periodicals, Inc. Numer Methods Partial Differential Eq, 2006

Published

2006

10. A Crank-Nicolson Petrov-Galerkin method with quadrature for semi-linear parabolic problems

Author

Bernard Bialecki, Mahadevan Ganesh, and Kassem Mustapha

Subjects

Numerical Analysis, Discretization, Applied Mathematics, Mathematical analysis, Petrov–Galerkin method, Tanh-sinh quadrature, Gauss–Kronrod quadrature formula, Mathematics::Numerical Analysis, Quadrature (mathematics), Computational Mathematics, symbols.namesake, symbols, Crank–Nicolson method, Gaussian quadrature, Analysis, Clenshaw–Curtis quadrature, Mathematics

Abstract

We propose and analyze an application of a fully discrete C2 spline quadrature Petrov-Galerkin method for spatial discretization of semi-linear parabolic initial-boundary value problems on rectangular domains. We prove second order in time and optimal order H1 norm convergence in space for the extrapolated Crank-Nicolson quadrature Petrov-Galerkin scheme. We demonstrate numerically both L2 and H1 norm optimal order convergence of the scheme even if the nonlinear source term is not smooth. © 2005 Wiley Periodicals, Inc. Numer Methods Partial Differential Eq, 2005.

Published

2005

11. Stabilization method for continuous approximation of transient convection problem

Author

Mohamed Bensaada, Dominique Sandri, and Driss Esselaoui

Subjects

Numerical Analysis, Cauchy stress tensor, Velocity gradient, Applied Mathematics, Constitutive equation, Mathematical analysis, Petrov–Galerkin method, Finite element method, Computational Mathematics, symbols.namesake, Euler's formula, symbols, Convection–diffusion equation, Analysis, Mathematics, Variable (mathematics)

Abstract

The aim of this work is to study a new finite element (FE) formulation for the approximation of nonsteady convection equation. Our approximation scheme is based on the Streamline Upwind Petrov Galerkin (SUPG) method for space variable, x, and a modified of the Euler implicit method for time variable, t. The most interest for this scheme lies in its application to resolve by continuous (FE) method the complex of viscoelastic fluid flow obeying an Oldroyd-B differential model; this constituted our aim motivation and allows us to treat the constitutive law equation, which expresses the relation between the stress tensor and the velocity gradient and includes tensorial transport term. To make the analysis of the method more clear, we first study, in this article this modified method for the advection equation. We point out the stability of this new method and the error estimate of the approximation solution is discussed. © 2004 Wiley Periodicals, Inc. Numer Methods Partial Differential Eq, 2005

Published

2004

12. A Petrov-Galerkin mixed finite element method with exponential fitting

Author

R. R. P. Van Nooyen

Subjects

Numerical Analysis, Discretization, Applied Mathematics, Mathematical analysis, Petrov–Galerkin method, Estimator, Mixed finite element method, Finite element method, Domain (mathematical analysis), Mathematics::Numerical Analysis, Exponential function, Computational Mathematics, Analysis, Mathematics, Extended finite element method

Abstract

We discuss a Petrov-Galerkin mixed finite element formulation of the semiconductor continuity equations on a rectangular domain. We give error estimates for equations that are in principle degenerate in the singularly perturbed case. We give arguments that indicate that the method is also effective in the singularly perturbed case. We develop a discretization that gives a higher-order accurate solution for use in an a posteriori error estimator. © 1995 John Wiley & Sons, Inc.

Published

1995

13. Long-time behavior of some Galerkin and Petrov-Galerkin methods for thermoelastic consolidation

Author

Marcio A. Murad and Abimael F. D. Loula

Subjects

Numerical Analysis, Mathematical optimization, Consolidation (soil), Applied Mathematics, Numerical analysis, Petrov–Galerkin method, Finite element method, Computational Mathematics, Thermoelastic damping, Heat flux, Applied mathematics, Exponential decay, Galerkin method, Analysis, Mathematics

Abstract

Numerical analysis of some finite element methods for the quasi-static thermoelastic consolidation problem of fluid-filled porous materials is presented for the case of smooth exact solutions. Taking advantage of the exponential decay of the error in the initial data with time, error estimates describing the long-time behavior of the semidiscrete approximation are presented and postprocessing techniques are proposed to improve the accuracy of the pore pressure, heat flux, and effective stress approximations. © 1995 John Wiley & Sons, Inc.

Published

1995

14. A Petrov-Galerkin method and boundary approximations for hyperbolic initial boundary-value problems

Author

D. M. Sloan and S. M. Jamieson

Subjects

Numerical Analysis, Applied Mathematics, Mathematical analysis, Petrov–Galerkin method, Boundary (topology), Mixed boundary condition, Singular boundary method, Elliptic boundary value problem, Computational Mathematics, Shooting method, Free boundary problem, Boundary value problem, Analysis, Mathematics

Published

1986