Difference between revisions of "Bloch modes in periodic waveguides"
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== Additional information == | == Additional information == | ||
− | Open '''rhombus.pro''' with Gmsh. The model will automatically compute the band diagram of Figure 3.16, p. 152 of Foundations Of Photonic Crystal Fibres<ref name=Zolla2005 />, using a finite element formulation with Floquet-Bloch conditions<ref name=Nicolet2004 />. You can double-click on any point in the diagram to visualize the corresponding eigenmode | + | Open '''rhombus.pro''' with Gmsh. The model will automatically compute the band diagram of [http://books.google.com/books?id=iVZXwXDswv0C&lpg=PP1&dq=isbn%3A1860945074&pg=PA152#v=onepage&q&f=false Figure 3.16, p. 152] of Foundations Of Photonic Crystal Fibres<ref name=Zolla2005 />, using a finite element formulation with Floquet-Bloch conditions<ref name=Nicolet2004 />. You can double-click on any point in the diagram to visualize the corresponding eigenmode, even while the calculation is running. |
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== References == | == References == |
Latest revision as of 08:58, 25 July 2015
Bloch modes in periodic waveguides.
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Download model archive (bloch_periodic_waveguides.zip) |
Additional information
Open rhombus.pro with Gmsh. The model will automatically compute the band diagram of Figure 3.16, p. 152 of Foundations Of Photonic Crystal Fibres[1], using a finite element formulation with Floquet-Bloch conditions[2]. You can double-click on any point in the diagram to visualize the corresponding eigenmode, even while the calculation is running.
References
- ↑ F. Zolla, G. Renversez, A. Nicolet, B. Kuhlmey, S. Guenneau, D. Felbacq, Foundations Of Photonic Crystal Fibres, Imperial College Press, 2005.
- ↑ A. Nicolet, S. Guenneau, C. Geuzaine, F. Zolla, Modelling of electromagnetic waves in periodic media with finite elements, Journal of Computational and Applied Mathematics 168 (1), 321-329, 2004.
Model developed by A. Nicolet, F. Zolla and C. Geuzaine.
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