Periodic structure analysis using a hybrid finite element method

McGrath, Daniel T.; Pyati, V.P.

doi:10.1029/96rs00869

Cited by 32 publications

(18 citation statements)

References 10 publications

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“…• φ i and φ To derive the system matrices corresponding to the discretization of the weak formulation (9) in such a Bloch-periodic basis, one could proceed as in Section 3.1 by modifying the connectivity matrices in the assembly process (with application of appropriate phase factors); however, the same matrices can also be obtained via row and column operations on the standard Neumann matrices. This follows directly from the relation of the Neumann and Bloch-periodic bases, as we now show.…”

Section: Schrödinger Equationmentioning

confidence: 99%

Classical and enriched finite element formulations for Bloch‐periodic boundary conditions

Sukumar

Pask

2008

Numerical Meth Engineering

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SUMMARYIn this paper, classical and enriched finite element formulations to impose Bloch-periodic boundary conditions are proposed. Bloch-periodic boundary conditions arise in the description of wave-like phenomena in periodic media. We consider the quantum-mechanical problem in a crystalline solid, and derive the weak formulation and matrix equations for the Schrödinger and Poisson equations in a parallelepiped unit cell under Bloch-periodic and periodic boundary conditions, respectively.For such second-order problems, these conditions consist of value-and derivative-periodic parts. The value-periodic part is enforced as an essential boundary condition by construction of a value-periodic basis, whereas the derivative-periodic part is enforced as a natural boundary condition in the weak formulation. We show that the resulting matrix equations can be obtained by suitably specifying the connectivity of element matrices in the assembly of the global matrices or by modifying the Neumann * Correspondence to: N. Sukumar, Department of Civil and Environmental Engineering, University of California, One Shields Avenue, Davis, CA 95616. E-mail: nsukumar@ucdavis.edu

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Section: Schrödinger Equationmentioning

confidence: 99%

Classical and enriched finite element formulations for Bloch‐periodic boundary conditions

Sukumar

Pask

2008

Numerical Meth Engineering

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“…Tsay and Pozar (1998) applied a hybrid MoM/Green's function method for printed arrays capable of modeling various volumetric inhomogeneities within the grounded substrate of a unit cell. D' Angelo and Mayergoyz (1996) and McGrath and Pyati (1996) employed the lowest order tetrahedral tangential vector nite elements (TVFEs) for modeling the electric eld within the unit cell and used a Floquet modal expansion to satisfy the radiation boundary conditions. Lucas and Fontana (1995) used a similar approach but applied tetrahedral TVFEs of order 1.5.…”

Section: Introductionmentioning

confidence: 99%

Hybrid Finite Element Methods for Array and FSS Analysis Using Multiresolution Elements and Fast Integral Techniques

Volakis¹,

Eibert²,

Filipović³

et al. 2002

Electromagnetics

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“…On the one hand, the FE-BIE approaches have become mature by now. In electromagnetic (EM) literature, they have proven their usefulness for a wide range of applications [Volakis et al, 1997;Eibert et al, 1999;Gedney et al, 1992;McGrath and Pyati, 1996;Rogier et al, 1996Rogier et al, , 2000a. On the other hand, FDTD-BIE formalisms proved to be more involved.…”

Section: Introductionmentioning

confidence: 99%

A new finite element‐FDTD‐boundary integral equation technique with biconjugate gradient solver for modeling electromagnetic problems in the frequency domain

Rogier

Zutter

2003

Radio Science

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[1] A new hybrid formalism in the frequency domain is presented, based on a combination of the boundary integral equation (BIE) technique, the finite element (FE) method and the finite difference time domain (FDTD) algorithm. An FE method and FDTD are used to describe the inhomogeneous parts of the simulation domain, whereas large homogeneous portions of the simulation space are modeled with a BIE. To solve the global matrix system efficiently, a biconjugate gradient solver is used. To calculate the matrix-vector products in each iteration step of the solution process, the system matrix is required for the FE and the BIE subregions. For FDTD subregions, we will either construct a system matrix or we will calculate matrix-vector products directly relying on FDTD. Guidelines will be given to choose the most efficient approach for each FDTD subdomain. To illustrate the efficiency of the new method and to compare the new approach with other (hybrid) methods, three representative configurations are studied.

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Periodic structure analysis using a hybrid finite element method

Cited by 32 publications

References 10 publications

Classical and enriched finite element formulations for Bloch‐periodic boundary conditions

Classical and enriched finite element formulations for Bloch‐periodic boundary conditions

Hybrid Finite Element Methods for Array and FSS Analysis Using Multiresolution Elements and Fast Integral Techniques

A new finite element‐FDTD‐boundary integral equation technique with biconjugate gradient solver for modeling electromagnetic problems in the frequency domain

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