Bodendiek/CurlCurl_3 | SuiteSparse Matrix Collection

Curl-Curl operator of 2nd order Maxwell's equations, A. Bodendiek

Name	CurlCurl_3
Group	Bodendiek
Matrix ID	2572
Num Rows	1,219,574
Num Cols	1,219,574
Nonzeros	13,544,618
Pattern Entries	13,544,618
Kind	Model Reduction Problem
Symmetric	Yes
Date	2012
Author	A. Bodendiek
Editor	T. Davis

Force-Directed Graph Visualization of Bodendiek/CurlCurl_3

Structural Rank	1,219,574
Structural Rank Full	true
Num Dmperm Blocks	1
Strongly Connect Components	1
Num Explicit Zeros	0
Pattern Symmetry	100%
Numeric Symmetry	100%
Cholesky Candidate	yes
Positive Definite	no
Type	real

Download	MATLAB Rutherford Boeing Matrix Market
Notes	Curl-Curl operator of 2nd order Maxwell's equations, A. Bodendiek From Andre Bodendiek, Institut Computational Mathematics, TU Braunschweig The following matrix collection consists of the curl-curl-operator of a second-order Maxwell's equations with PEC boundary conditions, i.e. E x n = 0, where E and n denote the electric field strength and the unit outer normal of the computational domain. The curl-curl-operator has been discretized using the Finite Element Method with first-order Nedelec elements resulting in the weak formulation 1/mu0 ( curl E, curl v ), where v resembles a test function of H(curl) and mu0 = 1.25 1e-9 H / mm denotes the magnetic permeability of vacuum, see [Hipt02]. In general, the underlying model problem of Maxwell's equations results from a Coplanar Waveguide, which will be considered for the analysis of parasitic effects in the development of new semiconductors. Since the corresponding dynamical systems are often high-dimensional, model order reduction techniques have become an appealing approach for the efficient simulation and accurate analysis of the parasitic effects. However, different kinds of model order techniques require the repeated solution of high-dimensional linear systems of the original model problem, see [Bai02,An09]. Therefore, the development of efficient solvers resembles an important task in model order reduction. Each matrix CurlCurl_<nr> consists of a different number of degrees of freedom, given in the following table: <nr> = 0: 11083 <nr> = 1: 226451 <nr> = 2: 806529 <nr> = 3: 1219574 <nr> = 4: 2380515 References. @ARTICLE{Bai02, author = {Z. Bai}, title = {Krylov subspace techniques for reduced-order modeling of large-scale dynamical systems}, journal = {Applied Numerical Mathematics}, year = {2002}, volume = {43}, pages = {9--44}, number = {1--2} } @ARTICLE{Hipt02, author = {R. Hiptmair}, title = {Finite elements in computational electromagnetism}, journal = {Acta Numerica, Cambridge University Press}, year = {2002}, pages = {237-339} } @BOOK{An09, title = {Approximation of {L}arge-{S}cale {D}ynamical {S}ystems}, publisher = {Society for Industrial Mathematics}, year = {2009}, author = {Athanasios C. Antoulas} }

Download

MATLAB Rutherford Boeing Matrix Market

Notes

Curl-Curl operator of 2nd order Maxwell's equations, A. Bodendiek    
                                                                     
From Andre Bodendiek, Institut Computational Mathematics,            
TU Braunschweig                                                      
                                                                     
The following matrix collection consists of the curl-curl-operator   
of a second-order Maxwell's equations with PEC boundary conditions,  
i.e. E x n = 0, where E and n denote the electric field strength     
and the unit outer normal of the computational domain. The           
curl-curl-operator has been discretized using the Finite Element     
Method with first-order Nedelec elements resulting in the weak       
formulation                                                          
                                                                     
   1/mu0 ( curl E, curl v ),                                         
                                                                     
where v resembles a test function of H(curl) and                     
mu0 = 1.25 1e-9 H / mm denotes the magnetic permeability of vacuum,  
see [Hipt02].                                                        
                                                                     
In general, the underlying model problem of Maxwell's equations      
results from a Coplanar Waveguide, which will be considered for      
the analysis of parasitic effects in the development of new          
semiconductors. Since the corresponding dynamical systems are often  
high-dimensional, model order reduction techniques have become an    
appealing approach for the efficient simulation and accurate analysis
of the parasitic effects. However, different kinds of model order    
techniques require the repeated solution of high-dimensional linear  
systems of the original model problem, see [Bai02,An09]. Therefore,  
the development of efficient solvers resembles an important task     
in model order reduction.                                            
                                                                     
Each matrix CurlCurl_<nr> consists of a different number of degrees  
of freedom, given in the following table:                            
                                                                     
<nr> = 0:   11083                                                    
<nr> = 1:  226451                                                    
<nr> = 2:  806529                                                    
<nr> = 3: 1219574                                                    
<nr> = 4: 2380515                                                    
                                                                     
References.                                                          
                                                                     
@ARTICLE{Bai02,                                                      
  author = {Z. Bai},                                                 
  title = {Krylov subspace techniques for reduced-order modeling     
    of large-scale dynamical systems},                               
  journal = {Applied Numerical Mathematics},                         
  year = {2002},                                                     
  volume = {43},                                                     
  pages = {9--44},                                                   
  number = {1--2}                                                    
}                                                                    
                                                                     
@ARTICLE{Hipt02,                                                     
  author = {R. Hiptmair},                                            
  title = {Finite elements in computational electromagnetism},       
  journal = {Acta Numerica, Cambridge University Press},             
  year = {2002},                                                     
  pages = {237-339}                                                  
}                                                                    
                                                                     
@BOOK{An09,                                                          
  title = {Approximation of {L}arge-{S}cale {D}ynamical {S}ystems},  
  publisher = {Society for Industrial Mathematics},                  
  year = {2009},                                                     
  author = {Athanasios C. Antoulas}                                  
}