Generalization of the boundary diffraction method for volume gratings

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Title: Generalization of the boundary diffraction method for volume gratings
Authors: Sheridan, John T.
Permanent link: http://hdl.handle.net/10197/3321
Date: 1-Feb-1994
Abstract: The boundary diffraction method (BDM) is an approximate method that permits the derivation of analytic solutions for the output beams, both forward and backward propagating, that arise from the fundamental nature of holographic gratings. The method is based on the assumption that the volume scatter inside the grating can be supplemented by boundary diffraction coefficients. The boundary diffraction method is used for analysis of thick transmission geometry gratings in a unified way that deals with both the slanted and the unslanted cases. During the analysis, evidence emerges for the superiority of the first-order two-wave beta-value method over the Kogelnik k-vector closure method. The BDM is then further generalized to the case of a volume transmission grating, index matched to its surroundings, and replayed normally on-Bragg, i.e., satisfying the Bragg condition for normal incidence. The analytic equations derived are compared with results calculated with the rigorous coupled-wave method.
Funding Details: Not applicable
Type of material: Journal Article
Publisher: Optical Society of America
Copyright (published version): 1994 Optical Society of America
Subject LCSH: Diffraction
Diffraction gratings
DOI: 10.1364/JOSAA.11.000649
Language: en
Status of Item: Not peer reviewed
Appears in Collections:Electrical and Electronic Engineering Research Collection

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