A Posteriori Error Estimates of Spectral Approximations for Second Order Partial Differential Equations in Spherical Geometries

In this paper, we investigate a posteriori error estimates of the Galerkin spectral methods for second-order equations, and propose a simple type of error estimator comprising expansion coefficients of known quantities such as the right-hand term. We first show that the errors of the numerical solut...

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Bibliographic Details
Published in:Journal of scientific computing 2022-01, Vol.90 (1), p.56, Article 56
Main Authors: Zhou, Jianwei, Li, Huiyuan, Zhang, Zhimin
Format: Article
Language:English
Subjects:
Algorithms
Approximation
Boundary value problems
Computational Mathematics and Numerical Analysis
Decay rate
Differential geometry
Efficiency
Error analysis
Estimates
Galerkin method
Mathematical and Computational Engineering
Mathematical and Computational Physics
Mathematics
Mathematics and Statistics
Partial differential equations
Poisson equation
Polynomials
Reaction-diffusion equations
Singular perturbation
Spectral methods
Spherical harmonics
Theoretical
Thermal expansion
Truncation errors
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Summary:In this paper, we investigate a posteriori error estimates of the Galerkin spectral methods for second-order equations, and propose a simple type of error estimator comprising expansion coefficients of known quantities such as the right-hand term. We first show that the errors of the numerical solution of the Poisson equation on the unit ball in arbitrary dimensions can be identified by the approximation errors of the (weighted) L 2 -projection of the right-hand function together with the non-homogeneous boundary function. This result indicates that the decay rate of the high frequency coefficients of the right-hand term in weighted orthogonal ball polynomials and of the boundary term in spherical harmonics serves as an ideal a posteriori error estimator. In the sequel, we establish a posteriori error estimates on the Galerkin spectral method applied to the singular perturbation problem of a reaction–diffusion equation on the unit ball. Again, the efficiency is given by the approximation errors of the weighted L 2 -projection of the right-hand function; while the reliability is determined by the truncation errors of the right-hand function together with exponentially decaying multiples of the low frequency coefficients, which also reveals that the a posterior error estimator is dominated by the decay rate of the high frequency coefficients of the right-hand term. Finally, numerical examples are presented to illustrate the theoretical results.
ISSN:0885-7474
1573-7691
DOI:10.1007/s10915-021-01696-5