Contemporary Holography

Cover
Half Title
Series Page
Title Page
Copyright Page
Dedication
Contents
Preface
Acknowledgments
Contributors
List of Figures
Chapter 1: Conventional Holography
	1.1. Introduction
	1.2. In-line Gabor holography
		1.2.0.1. Construction of hologram
		1.2.0.2. Reconstruction of hologram using normal incidence of reference beam
	1.3. Off-axis Holography
		1.3.1. Construction of off-axis holography
		1.3.2. Reconstruction of off-axis holography
	1.4. Polarization based holography
		1.4.1. Parallel polarization
		1.4.2. Perpendicular polarization
	1.5. Off-axis holography with 3D objects
		1.5.1. Reconstruction of virtual and real images
	1.6. Holographic magnifications
		1.6.1. Lateral Magnifications
		1.6.2. Longitudinal Magnifications
	1.7. Reflection holography
		1.7.1. Construction
		1.7.2. Reconstruction
	1.8. Practical demonstration of holography
Chapter 2: Conoscopic Holography
	2.1. Introduction
	2.2. Construction of Conoscopic Holography
	2.2.1. Theoretical explanation
		2.2.2. Construction of Conoscopic hologram
Chapter 3: Computer-Generated Holography
	3.1. Introduction
	3.2. Mathematical model
	3.3. Realization of computer-generated Holography
		3.3.1. Realization of Computer Generated Hologram using a Spatial Light Modulator
Chapter 4: Photorefractive dynamic holography
	4.1. Introduction
	4.2. Principle of dynamic photorefractive holography
		4.2.1. Photorefractive Effect
	4.2.2. Theoretical Explanation
		4.2.3. Two wave mixing in Photorefractive crystals
	4.3. Experimental techniques of photorefractive dynamic holography
		4.3.1. Introduction
		4.3.2. Photorefractive dynamic holography using Bi12SiO20 (Bismuth Silicon Oxide)
Chapter 5: Digital holography
	5.1. Introduction
	5.2. Principle of digital holography
	5.3. Recording on CCD and Sampling
		5.3.1. Reduction of imaging angle
		5.3.2. Conditions for reference beams
	5.4. Numerical Reconstruction Techniques
		5.4.1. Introduction
		5.4.2. Reconstruction using finite discrete Fresnel Transform
			5.4.2.1. Reconstruction of Real and Virtual image
			5.4.2.2. The D.C Term of Fresnel Transform
			5.4.2.3. Suppression of the D.C Term
			5.4.2.4. Suppression of twin images in digital holography
		5.4.3. Numerical reconstruction of digital hologram by convolution method
			5.4.3.1. Diffraction integral as a convolution
			5.4.3.2. Image Field size in convolution approach
	5.5. Phase shifting digital holography
		5.5.1. Introduction
		5.5.2. Dynamic phase shifting digital holography
		5.5.3. Quadrature dynamic phase shifting digital holography in two steps
		5.5.4. Geometric phase shifting color digital holography
		5.5.5. Reconstruction Procedure
		5.5.6. Geometric phase shifting digital holograpy using Michelson interferometer geometry
		5.5.7. Experimental Results and discussion
Chapter 6: Unconventional holography
	6.1. Coherence holography
		6.1.1. Introduction
		6.1.2. Principle of coherence holography
		6.1.3. Experimental procedure
		6.1.4. Experimental demonstration of coherence holography
Appendix A: Coherence of Optical waves
	A.1. Introduction
	A.2. Spatial Coherence
		A.2.1. Theoretical explanation
	A.3. Temporal coherence
		A.3.1. Introduction
		A.3.2. Theoretical Explanation
Appendix B: Rainbow holography
Appendix C: Anisotropic self-diffraction
Appendix D: Van Cittert–Zernike theorem
	D.1. Introduction
	D.2. Theoretical explanation
	D.3. Interpretation of Van Cittert–Zernike theorem
References
Index