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The acceleration of Method-of-Moment (MoM) calculations often relies on compression of blocks of the MoM impedance matrix. This can be carried out algebraically, operating exclusively on lines and columns of the matrix. Here, we focus on physically-based compression techniques. Approaches based on multipole decompositions and on complex plane wave expansions are compared from the perspective of the rank of the interaction matrix and its dependence on distance. A drawback of the complex plane-wave expansion is mitigated by defining a set of patterns that can be reused when computing interactions between any pair of blocks. © 2013 EurAAP
A mathematical link is provided between the Krylov subspace iterative approach based on the full ort...
A new method of moments (MoM) code is discussed. The code supports standard functionality, e.g. full...
A tailored version of the Characteristic Basis Function Method (CBFM) is presented as a matrix compr...
The acceleration of Method-of-Moment (MoM) calculations often relies on compression of blocks of the...
The acceleration of Method-of-Moment (MoM) calculations often relies on compression of blocks of the...
A new accuracy-controlable method for compressing the MoM impedance matrix of an electromagnetic pro...
We present a scheme to compress the method of moments (MoM) matrix, which is linear in complexity fo...
This paper addresses the direct (noniterative) solution of the method-of-moments (MoM) linear system...
A novel algorithm, the compressed block decomposition (CBD), is presented for highly accelerated dir...
Currently, the problem size that can be solved by the Method of Moments (MoM) is limited by the amou...
The multiscale compressed block decomposition algorithm (MS-CBD) is presented for highly accelerate...
In this work we present a new physics-based approach for formulating MoM problems based on the use o...
An innovative procedure is presented that allows the method of moments (MoM) analysis of large and c...
A comparison is presented between different algorithms for direct (non-iterative) accelerated solut...
The Method of Moments (MoM) is a general method for solving linear problems, including electromagnet...
A mathematical link is provided between the Krylov subspace iterative approach based on the full ort...
A new method of moments (MoM) code is discussed. The code supports standard functionality, e.g. full...
A tailored version of the Characteristic Basis Function Method (CBFM) is presented as a matrix compr...
The acceleration of Method-of-Moment (MoM) calculations often relies on compression of blocks of the...
The acceleration of Method-of-Moment (MoM) calculations often relies on compression of blocks of the...
A new accuracy-controlable method for compressing the MoM impedance matrix of an electromagnetic pro...
We present a scheme to compress the method of moments (MoM) matrix, which is linear in complexity fo...
This paper addresses the direct (noniterative) solution of the method-of-moments (MoM) linear system...
A novel algorithm, the compressed block decomposition (CBD), is presented for highly accelerated dir...
Currently, the problem size that can be solved by the Method of Moments (MoM) is limited by the amou...
The multiscale compressed block decomposition algorithm (MS-CBD) is presented for highly accelerate...
In this work we present a new physics-based approach for formulating MoM problems based on the use o...
An innovative procedure is presented that allows the method of moments (MoM) analysis of large and c...
A comparison is presented between different algorithms for direct (non-iterative) accelerated solut...
The Method of Moments (MoM) is a general method for solving linear problems, including electromagnet...
A mathematical link is provided between the Krylov subspace iterative approach based on the full ort...
A new method of moments (MoM) code is discussed. The code supports standard functionality, e.g. full...
A tailored version of the Characteristic Basis Function Method (CBFM) is presented as a matrix compr...
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