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Statements

Subject Item
n2:RIV%2F67985882%3A_____%2F12%3A00396896%21RIV14-AV0-67985882
rdf:type
n3:Vysledek skos:Concept
dcterms:description
n this contribution we present the basics of four frequency-domain modal methods for numerical modelling of advanced photonic and plasmonic structures that have been independently developed at three collaborating institutions within a joint project. The rigorous coupled-wave analysis (RCWA) method originally built up for modelling periodic 1D and crossed diffraction grating structures was developed and adapted also for modelling 3D photonic waveguiding structures. A very similar but independently developed bi-directional mode expansion propagation method (BEP) based on Fourier series has been extended for modelling 3D structures, too. Implementation of adaptive spatial resolution technique helps reduce the number of expansion terms and thus dramatically increase the numerical efficiency of the methods. Another two variants of the BEP approach differ in the way how the eigenmodes of the structures are searched for; they exploit the finite-difference and the finite-element methods, respectively. Results of modelling of two simple structures (effective indices of guided modes in a SOI photonic wire and reflections from a gap in the waveguide) are mutually compared and other results of modelling of some other promising photonic and plasmonic nanostructures as subwavelength grating waveguides and hybrid dielectric-plasmonic gap waveguides are finally presented, too n this contribution we present the basics of four frequency-domain modal methods for numerical modelling of advanced photonic and plasmonic structures that have been independently developed at three collaborating institutions within a joint project. The rigorous coupled-wave analysis (RCWA) method originally built up for modelling periodic 1D and crossed diffraction grating structures was developed and adapted also for modelling 3D photonic waveguiding structures. A very similar but independently developed bi-directional mode expansion propagation method (BEP) based on Fourier series has been extended for modelling 3D structures, too. Implementation of adaptive spatial resolution technique helps reduce the number of expansion terms and thus dramatically increase the numerical efficiency of the methods. Another two variants of the BEP approach differ in the way how the eigenmodes of the structures are searched for; they exploit the finite-difference and the finite-element methods, respectively. Results of modelling of two simple structures (effective indices of guided modes in a SOI photonic wire and reflections from a gap in the waveguide) are mutually compared and other results of modelling of some other promising photonic and plasmonic nanostructures as subwavelength grating waveguides and hybrid dielectric-plasmonic gap waveguides are finally presented, too
dcterms:title
Modal methods for 3D modelling of advanced photonic structures Modal methods for 3D modelling of advanced photonic structures
skos:prefLabel
Modal methods for 3D modelling of advanced photonic structures Modal methods for 3D modelling of advanced photonic structures
skos:notation
RIV/67985882:_____/12:00396896!RIV14-AV0-67985882
n3:predkladatel
n4:ico%3A67985882
n5:aktivita
n10:I
n5:aktivity
I
n5:dodaniDat
n16:2014
n5:domaciTvurceVysledku
n13:8443793
n5:druhVysledku
n21:D
n5:duvernostUdaju
n17:S
n5:entitaPredkladatele
n12:predkladatel
n5:idSjednocenehoVysledku
150880
n5:idVysledku
RIV/67985882:_____/12:00396896
n5:jazykVysledku
n6:eng
n5:klicovaSlova
finite-difference method; finite-element method; plasmonics
n5:klicoveSlovo
n15:finite-element%20method n15:plasmonics n15:finite-difference%20method
n5:kontrolniKodProRIV
[165231143EA0]
n5:mistoKonaniAkce
Coventry
n5:mistoVydani
NEW YORK
n5:nazevZdroje
International Conference on Transparent Optical Networks-ICTON 2012
n5:obor
n9:JA
n5:pocetDomacichTvurcuVysledku
1
n5:pocetTvurcuVysledku
5
n5:rokUplatneniVysledku
n16:2012
n5:tvurceVysledku
Čtyroký, Jiří Petráček, J. Luksch, J. Richter, I. Kwiecien, P.
n5:typAkce
n20:WRD
n5:zahajeniAkce
2012-07-02+02:00
s:issn
2161-2056
s:numberOfPages
4
n14:doi
10.1109/ICTON.2012.6253755
n19:hasPublisher
IEEE
n8:isbn
978-1-4673-2228-7