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Numerical solution of the time-harmonic Maxwell equations and incompressible magnetohydrodynamics problems Li, Dan
Abstract
The goal of this thesis is to develop efficient numerical solvers for the time-harmonic Maxwell equations and for incompressible magnetohydrodynamics problems. The thesis consists of three components. In the first part, we present a fully scalable parallel iterative solver for the time-harmonic Maxwell equations in mixed form with small wave numbers. We use the lowest order Nedelec elements of the first kind for the approximation of the vector field and standard nodal elements for the Lagrange multiplier associated with the divergence constraint. The corresponding linear system has a saddle point form, with inner iterations solved by preconditioned conjugate gradients. We demonstrate the performance of our parallel solver on problems with constant and variable coefficients with up to approximately 40 million degrees of freedom. Our numerical results indicate very good scalability with the mesh size, on uniform, unstructured and locally refined meshes. In the second part, we introduce and analyze a mixed finite element method for the numerical discretization of a stationary incompressible magnetohydrodynamics problem, in two and three dimensions. The velocity field is discretized using divergence-conforming Brezzi-Douglas-Marini (BDM) elements and the magnetic field is approximated by curl-conforming Nedelec elements. Key features of the method are that it produces exactly divergence-free velocity approximations, and that it correctly captures the strongest magnetic singularities in non-convex polyhedral domains. We prove that the energy norm of the error is convergent in the mesh size in general Lipschitz polyhedra under minimal regularity assumptions, and derive nearly optimal a-priori error estimates for the two-dimensional case. We present a comprehensive set of numerical experiments, which indicate optimal convergence of the proposed method for two-dimensional as well as three-dimensional problems. Finally, in the third part we investigate preconditioned Krylov iterations for the discretized stationary incompressible magnetohydrodynamics problems. We propose a preconditioner based on efficient preconditioners for the Maxwell and Navier-Stokes sub-systems. We show that many of the eigenvalues of the preconditioned system are tightly clustered, and hence, rapid convergence is accomplished. Our numerical results show that this approach performs quite well.
Item Metadata
| Title |
Numerical solution of the time-harmonic Maxwell equations and incompressible magnetohydrodynamics problems
|
| Creator | |
| Publisher |
University of British Columbia
|
| Date Issued |
2010
|
| Description |
The goal of this thesis is to develop efficient numerical solvers for the time-harmonic
Maxwell equations and for incompressible magnetohydrodynamics problems.
The thesis consists of three components. In the first part, we present a fully
scalable parallel iterative solver for the time-harmonic Maxwell equations in mixed
form with small wave numbers. We use the lowest order Nedelec elements of the
first kind for the approximation of the vector field and standard nodal elements for
the Lagrange multiplier associated with the divergence constraint. The corresponding
linear system has a saddle point form, with inner iterations solved by preconditioned conjugate gradients. We demonstrate the performance of
our parallel solver on problems with constant and variable coefficients with up to
approximately 40 million degrees of freedom. Our numerical results indicate very
good scalability with the mesh size, on uniform, unstructured and locally refined
meshes.
In the second part, we introduce and analyze a mixed finite element method for
the numerical discretization of a stationary incompressible magnetohydrodynamics
problem, in two and three dimensions. The velocity field is discretized using
divergence-conforming Brezzi-Douglas-Marini (BDM) elements and the magnetic
field is approximated by curl-conforming Nedelec elements. Key features of the
method are that it produces exactly divergence-free velocity approximations, and
that it correctly captures the strongest magnetic singularities in non-convex polyhedral
domains. We prove that the energy norm of the error is convergent in the
mesh size in general Lipschitz polyhedra under minimal regularity assumptions,
and derive nearly optimal a-priori error estimates for the two-dimensional case. We
present a comprehensive set of numerical experiments, which indicate optimal convergence of the proposed method for two-dimensional as well as three-dimensional
problems.
Finally, in the third part we investigate preconditioned Krylov iterations for
the discretized stationary incompressible magnetohydrodynamics problems. We
propose a preconditioner based on efficient preconditioners for the Maxwell and
Navier-Stokes sub-systems. We show that many of the eigenvalues of the preconditioned
system are tightly clustered, and hence, rapid convergence is accomplished.
Our numerical results show that this approach performs quite well.
|
| Genre | |
| Type | |
| Language |
eng
|
| Date Available |
2010-12-07
|
| Provider |
Vancouver : University of British Columbia Library
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| Rights |
Attribution-NonCommercial-NoDerivatives 4.0 International
|
| DOI |
10.14288/1.0051989
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| URI | |
| Degree | |
| Program | |
| Affiliation | |
| Degree Grantor |
University of British Columbia
|
| Graduation Date |
2011-05
|
| Campus | |
| Scholarly Level |
Graduate
|
| Rights URI | |
| Aggregated Source Repository |
DSpace
|
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Rights
Attribution-NonCommercial-NoDerivatives 4.0 International