Common Volume Multiplexing Technigues Coupled Wave Theory Derivation of Angular Selectivity...
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Transcript of Common Volume Multiplexing Technigues Coupled Wave Theory Derivation of Angular Selectivity...
Common Volume Multiplexing Technigues Coupled Wave Theory Derivation of Angular Selectivity Experimental Study of Angular Selectivity Optimum Beam Ratio Parameter Optimization For Holographic Disk Recording Time Schedule Holographic Recording Materials SNR Improving Technique Crystal Quality Dynamic Range Metric Angle-dependent Diffraction Efficiency Coherent Optical Correlators The Direct Optical Correlation Experiment(at NIST) Holographic 3-D Disk System Proposed by SONY Non-volatile holographic storage in doubly doped lithium niobate crystals (Korean) Influence of Phase Masks on Fourier Transform Hologram Holographic storage using shift multiplexing Channel codes for digital holographic data storage Holographic Medium and process for use thereof Multilayer volume holographic optical memory Phase correlation multiplex holography Volume hologram scheme using optical fiber for spatial multiplexing Phase code multiplexing
HDDS Seminar Sources : http://holospace.dwe.co.kr/
Coupled wave theory
Coupled wave theory
Contents
Coupled Wave Theory for Thick Hologram GratingsModel of Hologram Grating for AnalysisSinusoidal GratingsAssumption for AnalysisWave Propagation in the GratingCoupling ConstantCoupling ConstantTotal Electric Field in the GratingRelationship Between Propagation Vectors( , ) and Grating Vector( ) Bragg ConditionDerivation of Bragg ConditionDephasing MeasureDerivation of Dephasing MeasureThe Coupled Wave Equation General Solution of the Coupled Wave Equation Boundary Conditions for Transmission & Reflection HologramDefinition of the Diffraction EfficiencySolution for Transmission and Reflection HologramsDiffraction Efficiency of Lossless Dielectric Gratings(Transmission Type)Angular and Wavelength Sensitivity of Lossless Dielectric Gratings ( Transmission Type)Diffraction Efficiency of Lossy & No Slant Dielectric Gratings (Transmission Type)Influence of loss on the angular sensitivity of a dielectric grating (Transmission Type)Diffraction Efficiency of Lossy & Slant Dielectric Gratings (Transmission Type)Derivation of Slant Factor in Case of Bragg IncidenceInfluence of loss on the efficiency of a slanted dielectric grating (Transmission Type)Recording Geometry in a Holographic Memory SystemRelationship between Grating Angle and Recording Geometry Angular SelectivityDerivation of Angular SelectivityFull Refraction Condition & Critical AngleAngular Selectivity According to Recording GeometryNumber of Angular Multiplexed Holograms “M”Diffraction Efficiency Dependency on Refractive Index Modulation Depth of the GratingCenteral Peak Broadening I Centeral Peak Broadening IIDiscussion about The Angular SelectivityTheoretical Recording KineticsExperimental Recording KineticsReference