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Low-data simulation of diffractive optical elements based on the zones geometry

Design and simulation of two-dimensional diffractive optical elements are often limited by the amount of data required to represent the element in the computer's memory. We present a technique based on a geometrical description of the element, which requires fewer data than the traditional pixe...

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Published in:	Journal of modern optics 2002-09, Vol.49 (11), p.1801-1809
Main Authors:	RIPOLL, OLIVIER, KETTUNEN, VILLE, PETER HERZIG, HANS
Format:	Article
Language:	English
Subjects:	Diffraction and scattering Exact sciences and technology Filters, zone plates, and polarizers Fundamental areas of phenomenology (including applications) Gratings Optical elements, devices, and systems Optics Physics Wave optics
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container_title	Journal of modern optics
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creator	RIPOLL, OLIVIER KETTUNEN, VILLE PETER HERZIG, HANS
description	Design and simulation of two-dimensional diffractive optical elements are often limited by the amount of data required to represent the element in the computer's memory. We present a technique based on a geometrical description of the element, which requires fewer data than the traditional pixel description. Moreover, the element is being described more accurately and consequently the pixel-related artefacts are suppressed. This technique can be used for both periodic and non-periodic structures of large dimensions under Fraunhofer or Fresnel approximations. We apply the method to analysis of far-field beam-shaping elements and discuss possible extensions and refinements of the technique.
doi_str_mv	10.1080/09500340210140524
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source	Taylor and Francis Science and Technology Collection
subjects	Diffraction and scattering Exact sciences and technology Filters, zone plates, and polarizers Fundamental areas of phenomenology (including applications) Gratings Optical elements, devices, and systems Optics Physics Wave optics
title	Low-data simulation of diffractive optical elements based on the zones geometry
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