Analog and Digital Holography with MATLAB (Press Monograph)

Title Page
Publishing Notes
Table of Contents
Preface
List of Acronyms & Abbreviations
1. Introduction and Preliminaries
	1.1 History of Holography
		1.1.1 Introduction
		1.1.2 Types of holograms
		1.1.3 Holographic recording media
	1.2 Scalar Theory of Diffraction
		1.2.1 Maxwell’s equations
		1.2.2 Spatial frequency transfer function & Fresnel diffraction
		1.2.3 Fraunhofer diffraction
		1.2.4 Fourier transform property of an ideal lens
		1.2.5 Gaussian beam optics
		1.2.6 q-transformation of Gaussian beams
		1.2.7 Focusing a Gaussian beam
	1.3 Example 1: MATLAB Code for Calculating Diffraction with the Fast Fourier Transform
	1.4 Example 2: MATLAB Code for Calculating Forward & Backward Gaussian Beam Propagation
	1.5 Example 3: MATLAB Code for Gaussian Beam Propagationthrough a Lens
	1.6 Generalized Diffraction Example via the Fresnel Transform
	References
2. Analog Holography,Holographic Interferometry, and Phase-Shifting Holographic Interferometry
	2.1 Fourier Optics Theory
	2.2 Analog Holography Theory & Setups
	2.3 Analog Holographic Interferometry Theory & Setups
	2.4 Phase Unwrapping in 1D & 2D
	2.5 Application of Phase Unwrapping in Holographic Interferometry
	2.6 Phase-Shifting Holography through Dynamic Holographyand Self-Diffraction
	References
3. Fringe Deciphering Techniques Applied to Analog Holographic Interferometry
	3.1 Introduction
	3.2 Interferogram Processing Using Frequency Techniques
		3.2.1 Demodulating simulated fringes due to a tilt
		3.2.2 Demodulating fringes embedded with a carrier
	3.3 Interferogram Processing Using Fringe Orientation & Fringe Direction
		3.3.1 Definition of fringe orientation & fringe direction
		3.3.2 Orientation computation methods
			3.3.2.1 Gradient-based method
			3.3.2.2 Plane-fit method
			3.3.2.3 Spin-filter method
			3.3.2.4 Fourier transform method
			3.3.2.5 Accumulate-differences method
			3.3.2.6 Comparison of the different methods
		3.3.3 Phase unwrapping & fringe direction computation usingregularized phase tracking
	3.4 Phase Demodulation Using the Hilbert TransformTechnique
	3.5 Fringe Skeletonization & Normalization
	3.6 Contrast Enhancement of Fringe Patterns
	3.7 Phase Unwrapping: Interferogram Analysis
		3.7.1 Path-dependent techniques
		3.7.2 Path-independent techniques
	References
4. Digital Holography & Digital Holographic Microscopy
	4.1 Basics of Digital Holography
	4.2 Digital Holography Reconstruction Algorithms
		4.2.1 Numerical reconstruction by the discrete Fresnel transformation
		4.2.2 Numerical reconstruction by the convolution approach
		4.2.3 Numerical reconstruction by the angular spectrum approach
	4.3 DC Suppression during Reconstruction
	4.4 Digital Holography Example
	4.5 Digital Holograms of Large Objects
	4.6 Digital Holographic Microscopy
	4.7 Digital Holographic Microscopy Example
	4.8 Optimization of the Fresnel Transform
	4.9 General Functions for Digital Holography Using MATLAB
	References
5. Digital Holographic Interferometry andPhase-Shifting DigitalHolography
	5.1 Digital Holographic Interferometry: Basic Principles
	5.2 Two-Illumination-Point Technique
	5.3 3D Stress & Strain Sensors from Three Digital Hologram Recordings
	5.4 Phase-Shifting Digital Holography
	5.5 Techniques to Perform Phase-Shifting Digital Holography
	5.6 One-Shot Phase-Shifting Digital Holography Using Wave Plates
	5.7 General Functions for Digital Holographic Interferometry & Phase-Shifting Digital Holography Using MATLAB
	References
6. Digital Holographic Tomography
	6.1 Introduction
	6.2 Single-Shot Optical Tomography Using the MultiplicativeTechnique (SHOT-MT)
	6.3 Single-Shot Optical Tomography Using the Radon Transform Technique
	6.4 Recording Considerations for Holographic Tomography
		6.4.1 Multiple-angle, single-exposure methods
		6.4.2 Multiple-angle, multiple-exposure methods
		6.4.3 Microscopic tomography methods
		6.4.4 Angular sampling considerations
	6.5 Examples of Digital Holographic Tomography Using MATLAB
	References
7. Multiwavelength Digital Holography
	7.1 Holographic Contouring
	7.2 Principle of Multiwavelength Digital Holography
	7.3 Hierarchical Phase Unwrapping
	7.4 Multiwavelength Digital Holography
	7.5 Multiwavelength Digital Holography with Spatial Heterodyning
	7.6 Multiwavelength Digital Holographic Microscopy
	7.7 Multiwavelength Digital Holographic Microscopy with Spatial Heterodyning
	7.8 Holographic Volume-Displacement Calculations via Multiwavelength Digital Holography
	7.9 Multiwavelength Digital Holography: Image-Type Setupand Results
	References
8. Computer-Generated Holography
	8.1 A Brief History
	8.2 Fourier Transform Holograms: Detour Method
	8.3 Phase-Only CG Hologram
	8.4 Gerchberg–Saxton Algorithm for Recording a CG Hologram
	8.5 Point-Source Holograms & the Wavefront RecordingPlane Method
	8.6 Recent Developments in CGH
		8.6.1 Fourier ping-pong algorithm
		8.6.2 Interference-based algorithms
		8.6.3 Diffraction-specific algorithm
		8.6.4 Binarization algorithms
	8.7 CGH-based Display Systems
		8.7.1 Advantages
		8.7.2 Challenges
		8.7.3 Computational loads
	References
9. Compressive Sensing & Compressive Holography
	9.1 Compressive Sensing: Background
	9.2 Compressive Holography
	9.3 Experimental Setups & MATLAB Examples
	References
10. Contemporary Topics in Holography
	10.1 Transport-of-Intensity Imaging
	10.2 Nonlinear Holography
	10.3 Coherence Holography
	10.4 Polarization Imaging Using Digital Holography
	References
11. Progress in Stereoscopic, Head-Mounted, Multiview, Depth-Fused, Volumetric, andHolographic 3D Displays
	11.1 Introduction to 3D Displays
		11.1.1 Characteristics of an optimal 3D display
		11.1.2 Display-technology depth cues related to the humanvisual system
	11.2 Stereoscopic 3D Displays
		11.2.1 Spectral-based stereoscopic display (anaglyph)
		11.2.2 Polarization-based stereoscopic display
		11.2.3 Alternate-frame stereoscopic display
	11.3 Head-Mounted Displays (HMDs)
	11.4 Autostereoscopic 3D Displays
		11.4.1 Multiview 3D display technology
			11.4.1.1 Introduction to different multiview systems
			11.4.1.2 Occlusion-based system
			11.4.1.3 Refraction-based system
			11.4.1.4 Reflection-based system
			11.4.1.5 Diffraction-based system
			11.4.1.6 Projection-based system
			11.4.1.7 Super multiview (SMV) 3D display
			11.4.1.8 Head-tracking autostereoscopic 3D display
			11.4.1.9 Directional-backlight autostereoscopic 3D display
		11.4.2 Depth-fused 3D display technology
		11.4.3 Volumetric 3D display technology
			11.4.3.1 Passive static-screen display
			11.4.3.2 Active static-screen display
			11.4.3.3 Passive swept-screen display
			11.4.3.4 Active swept-screen display
		11.4.4 Holographic 3D display technology
			11.4.4.1 Spatial light modulators (SLMs)
			11.4.4.2 MIT holographic 3D displays: holovideo
			11.4.4.3 SeeReal 3D displays
			11.4.4.4 Zebra holographic 3D displays
			11.4.4.5 QinetiQ holographic 3D displays
			11.4.4.6 IMEC holographic 3D display
			11.4.4.7 HOlographic ReconstructioN (HORN)
			11.4.4.8 Image hologram
			11.4.4.9 Coherent stereogram
			11.4.4.10 NICT 3D holographic system
			11.4.4.11 University of Arizona’s updatable holographic display
	11.5 Comparison of the Different 3D Display Techniques
	11.6 Commonly Misunderstood Nonholographic, Non-3D Displays
		11.6.1 Pepper’s ghost illusion
		11.6.2 Heliodisplay
	References
Index
CD-ROM Files