Waveguide-Based Spatial Light Modulators for Use in Holographic Video Displays

Film display holograms typically diffract light over a wide enough view-angle to be viewed, directly, without intervening optics. However, all holographic video displays must use optics beyond the hologram surface to overcome the challenges of small display extent and low diffraction angle by using...

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Main Author: Qaderi, Kamran
Format: Others
Published: BYU ScholarsArchive 2018
Subjects:
Online Access:https://scholarsarchive.byu.edu/etd/7094
https://scholarsarchive.byu.edu/cgi/viewcontent.cgi?article=8094&context=etd
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spelling ndltd-BGMYU2-oai-scholarsarchive.byu.edu-etd-80942019-05-16T03:38:42Z Waveguide-Based Spatial Light Modulators for Use in Holographic Video Displays Qaderi, Kamran Film display holograms typically diffract light over a wide enough view-angle to be viewed, directly, without intervening optics. However, all holographic video displays must use optics beyond the hologram surface to overcome the challenges of small display extent and low diffraction angle by using some form of demagnification and derotation. We report a leaky mode waveg- uide spatial light modulator (SLM) with sufficiently high angular diffraction to obviate the need for demagnification in scanned aperture systems. This was achieved by performing a number of experiments to determine the depth of the annealed, proton-exchanged waveguide which corresponded to a maximized diffracted angle. Diffraction sweeps were recorded in excess of 19.5<°> for 632.8 nm light which is above the 15<°> required for direct view display.Moreover, we present a paired set of waveguide SLMs capable of a maximum light deflection nearing 28<°> for red. This deflection, which is several times larger than the angular sweep of current, state-of-the-art modulators, is made possible by the unilateral, near-collinear waveguide nature of the leaky mode interaction. The ability to double angular output in this way, which is either not possible or not practical in other SLMs, is possible in leaky mode devices, thanks to the absence of zero-order light and the lack of high-order outputs. This combined structure has angu- lar deflection high enough to enable color holographic video monitors that do not require angular magnification. Furthermore, the low cost and high angular deflection of these devices may make it possible to make large arrays for flat-screen video holography.One improvement that could be made to the current setup would be to increase the device<&trade>s diffraction efficiency. One highly influential factor of diffraction efficiency for a Bragg-regime surface acoustic wave (SAW) grating is the length of the interaction between the light and the grating. In this work, we have shown that guided light in a reverse proton exchanged (RPE) waveguide experiences less loss. This enables us to create longer devices which eventually results in devices with higher diffraction efficiency.We have also researched on LCoS SLMs and used them for two different applications: (a) photophoretic-trap volumetric displays and (b) holographic video displays. In the first case, aberrations including spherical, astigmatism, and coma can make particles to trap tighter in the focal point of the beam. Also, a new approach for holographic computations is presented which uses the electromagnetic nature of light in Maxwell Equations to find a unique phase map for every specific 3D object in space. 2018-03-01T08:00:00Z text application/pdf https://scholarsarchive.byu.edu/etd/7094 https://scholarsarchive.byu.edu/cgi/viewcontent.cgi?article=8094&amp;context=etd http://lib.byu.edu/about/copyright/ All Theses and Dissertations BYU ScholarsArchive Holography holographic video displays 3D displays spatial Light modulators leaky mode waveguide light modulators proton exchange Engineering
collection NDLTD
format Others
sources NDLTD
topic Holography
holographic video displays
3D displays
spatial Light modulators
leaky mode waveguide light modulators
proton exchange
Engineering
spellingShingle Holography
holographic video displays
3D displays
spatial Light modulators
leaky mode waveguide light modulators
proton exchange
Engineering
Qaderi, Kamran
Waveguide-Based Spatial Light Modulators for Use in Holographic Video Displays
description Film display holograms typically diffract light over a wide enough view-angle to be viewed, directly, without intervening optics. However, all holographic video displays must use optics beyond the hologram surface to overcome the challenges of small display extent and low diffraction angle by using some form of demagnification and derotation. We report a leaky mode waveg- uide spatial light modulator (SLM) with sufficiently high angular diffraction to obviate the need for demagnification in scanned aperture systems. This was achieved by performing a number of experiments to determine the depth of the annealed, proton-exchanged waveguide which corresponded to a maximized diffracted angle. Diffraction sweeps were recorded in excess of 19.5<°> for 632.8 nm light which is above the 15<°> required for direct view display.Moreover, we present a paired set of waveguide SLMs capable of a maximum light deflection nearing 28<°> for red. This deflection, which is several times larger than the angular sweep of current, state-of-the-art modulators, is made possible by the unilateral, near-collinear waveguide nature of the leaky mode interaction. The ability to double angular output in this way, which is either not possible or not practical in other SLMs, is possible in leaky mode devices, thanks to the absence of zero-order light and the lack of high-order outputs. This combined structure has angu- lar deflection high enough to enable color holographic video monitors that do not require angular magnification. Furthermore, the low cost and high angular deflection of these devices may make it possible to make large arrays for flat-screen video holography.One improvement that could be made to the current setup would be to increase the device<&trade>s diffraction efficiency. One highly influential factor of diffraction efficiency for a Bragg-regime surface acoustic wave (SAW) grating is the length of the interaction between the light and the grating. In this work, we have shown that guided light in a reverse proton exchanged (RPE) waveguide experiences less loss. This enables us to create longer devices which eventually results in devices with higher diffraction efficiency.We have also researched on LCoS SLMs and used them for two different applications: (a) photophoretic-trap volumetric displays and (b) holographic video displays. In the first case, aberrations including spherical, astigmatism, and coma can make particles to trap tighter in the focal point of the beam. Also, a new approach for holographic computations is presented which uses the electromagnetic nature of light in Maxwell Equations to find a unique phase map for every specific 3D object in space.
author Qaderi, Kamran
author_facet Qaderi, Kamran
author_sort Qaderi, Kamran
title Waveguide-Based Spatial Light Modulators for Use in Holographic Video Displays
title_short Waveguide-Based Spatial Light Modulators for Use in Holographic Video Displays
title_full Waveguide-Based Spatial Light Modulators for Use in Holographic Video Displays
title_fullStr Waveguide-Based Spatial Light Modulators for Use in Holographic Video Displays
title_full_unstemmed Waveguide-Based Spatial Light Modulators for Use in Holographic Video Displays
title_sort waveguide-based spatial light modulators for use in holographic video displays
publisher BYU ScholarsArchive
publishDate 2018
url https://scholarsarchive.byu.edu/etd/7094
https://scholarsarchive.byu.edu/cgi/viewcontent.cgi?article=8094&amp;context=etd
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