Combined LEGO-eigencurrent approach for enhanced solution of electrically large 2-D EBG structures

D.J. Duque Guerra; V. Lancellotti; B.P. Hon, de

Combined LEGO-eigencurrent approach for enhanced solution of electrically large 2-D EBG structures

D.J. Duque Guerra, V. Lancellotti, B.P. Hon, de

Onderzoeksoutput: Hoofdstuk in Boek/Rapport/Congresprocedure › Conferentiebijdrage › Academic › peer review

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We combine the linear embedding via Green's operators (LEGO) and the eigencurrent expansion method (EEM) to efficiently deal with 2-D electrically large electromagnetic band-gap (EBG) structures. In LEGO, the composite structure is broken up into elements called "bricks" that are characterized through scattering operators by invoking Love's equivalence principle. The problem is then formulated through an integral equation involving the total inverse scattering operator S-1 of the structure. The resulting equation is solved by the method of moments (MoM) and the EEM, which allows for considerable reduction in the size of the resulting MoM matrix. Therefore, it enables us to handle relatively large structures.

Originele taal-2	Engels
Titel	Proceedings of the Fourth European Conference on Antennas and Propagation (EuCap), 12-16 April 2010, Barcelona, Spain
Plaats van productie	Piscataway
Uitgeverij	Institute of Electrical and Electronics Engineers
Pagina's	1-5
ISBN van geprinte versie	978-1-4244-6431-9
Status	Gepubliceerd - 2010

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title = "Combined LEGO-eigencurrent approach for enhanced solution of electrically large 2-D EBG structures",

abstract = "We combine the linear embedding via Green's operators (LEGO) and the eigencurrent expansion method (EEM) to efficiently deal with 2-D electrically large electromagnetic band-gap (EBG) structures. In LEGO, the composite structure is broken up into elements called {"}bricks{"} that are characterized through scattering operators by invoking Love's equivalence principle. The problem is then formulated through an integral equation involving the total inverse scattering operator S-1 of the structure. The resulting equation is solved by the method of moments (MoM) and the EEM, which allows for considerable reduction in the size of the resulting MoM matrix. Therefore, it enables us to handle relatively large structures.",

author = "{Duque Guerra}, D.J. and V. Lancellotti and {Hon, de}, B.P.",

year = "2010",

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Combined LEGO-eigencurrent approach for enhanced solution of electrically large 2-D EBG structures. / Duque Guerra, D.J.; Lancellotti, V.; Hon, de, B.P.
Proceedings of the Fourth European Conference on Antennas and Propagation (EuCap), 12-16 April 2010, Barcelona, Spain. Piscataway: Institute of Electrical and Electronics Engineers, 2010. blz. 1-5.

Onderzoeksoutput: Hoofdstuk in Boek/Rapport/Congresprocedure › Conferentiebijdrage › Academic › peer review

TY - GEN

T1 - Combined LEGO-eigencurrent approach for enhanced solution of electrically large 2-D EBG structures

AU - Duque Guerra, D.J.

AU - Lancellotti, V.

AU - Hon, de, B.P.

PY - 2010

Y1 - 2010

N2 - We combine the linear embedding via Green's operators (LEGO) and the eigencurrent expansion method (EEM) to efficiently deal with 2-D electrically large electromagnetic band-gap (EBG) structures. In LEGO, the composite structure is broken up into elements called "bricks" that are characterized through scattering operators by invoking Love's equivalence principle. The problem is then formulated through an integral equation involving the total inverse scattering operator S-1 of the structure. The resulting equation is solved by the method of moments (MoM) and the EEM, which allows for considerable reduction in the size of the resulting MoM matrix. Therefore, it enables us to handle relatively large structures.

AB - We combine the linear embedding via Green's operators (LEGO) and the eigencurrent expansion method (EEM) to efficiently deal with 2-D electrically large electromagnetic band-gap (EBG) structures. In LEGO, the composite structure is broken up into elements called "bricks" that are characterized through scattering operators by invoking Love's equivalence principle. The problem is then formulated through an integral equation involving the total inverse scattering operator S-1 of the structure. The resulting equation is solved by the method of moments (MoM) and the EEM, which allows for considerable reduction in the size of the resulting MoM matrix. Therefore, it enables us to handle relatively large structures.

M3 - Conference contribution

SN - 978-1-4244-6431-9

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BT - Proceedings of the Fourth European Conference on Antennas and Propagation (EuCap), 12-16 April 2010, Barcelona, Spain

PB - Institute of Electrical and Electronics Engineers

CY - Piscataway

ER -

Combined LEGO-eigencurrent approach for enhanced solution of electrically large 2-D EBG structures

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