04629nam 2200949z- 450 991036774470332120231214133446.03-03921-829-8(CKB)4100000010106270(oapen)https://directory.doabooks.org/handle/20.500.12854/51783(EXLCZ)99410000001010627020202102d2019 |y 0engurmn|---annantxtrdacontentcrdamediacrrdacarrierLiquid Crystal on Silicon Devices: Modeling and Advanced Spatial Light Modulation ApplicationsMDPI - Multidisciplinary Digital Publishing Institute20191 electronic resource (172 p.)3-03921-828-X Liquid Crystal on Silicon (LCoS) has become one of the most widespread technologies for spatial light modulation in optics and photonics applications. These reflective microdisplays are composed of a high-performance silicon complementary metal oxide semiconductor (CMOS) backplane, which controls the light-modulating properties of the liquid crystal layer. State-of-the-art LCoS microdisplays may exhibit a very small pixel pitch (below 4 ?m), a very large number of pixels (resolutions larger than 4K), and high fill factors (larger than 90%). They modulate illumination sources covering the UV, visible, and far IR. LCoS are used not only as displays but also as polarization, amplitude, and phase-only spatial light modulators, where they achieve full phase modulation. Due to their excellent modulating properties and high degree of flexibility, they are found in all sorts of spatial light modulation applications, such as in LCOS-based display systems for augmented and virtual reality, true holographic displays, digital holography, diffractive optical elements, superresolution optical systems, beam-steering devices, holographic optical traps, and quantum optical computing. In order to fulfil the requirements in this extensive range of applications, specific models and characterization techniques are proposed. These devices may exhibit a number of degradation effects such as interpixel cross-talk and fringing field, and time flicker, which may also depend on the analog or digital backplane of the corresponding LCoS device. The use of appropriate characterization and compensation techniques is then necessary.Liquid Crystal on Silicon Devicesaberration compensationholographic and volume memoriesachromatic lenshead-up displaysphase characterizationholographic displayspatial resolutionspatial light modulatorzoom lenssolitontransmission matrixhead-mounted displaysdiffractionparallel-alignedliquid-crystal on siliconphase measurementmultimode fiberdigital holographychromatic aberrationmultiorder diffractive lensholographyphase accuracyinterferencecomputer generated hologramoptical manipulationspeckle suppressionphase modulationtransparent modelight scatteringferroelectricphase changeliquid-crystal-on-siliconimaging systemsLiquid Crystal on Silicon displaydiffractive optical elementliquid crystalsspatially anamorphic phenomenoncalibrationhead-up displayhelix-freephase precision and stabilitykinoformspatial light modulatorsphotopolymerdiffractive opticsmode division multiplexingliquid crystal on silicon deviceaugmented reality displaysholographic data storageliquid crystal spatial light modulatorharmonic lensfringing field effectliquid crystalLizana Ángelauth1314775Márquez AndrésauthBOOK9910367744703321Liquid Crystal on Silicon Devices: Modeling and Advanced Spatial Light Modulation Applications3031952UNINA