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E-raamat: Introduction to Modern Digital Holography: With Matlab

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(Virginia Polytechnic Institute and State University),
  • Formaat: PDF+DRM
  • Ilmumisaeg: 23-Jan-2014
  • Kirjastus: Cambridge University Press
  • Keel: eng
  • ISBN-13: 9781107722736
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Introduction to Modern Digital Holography: With MatlabSuurem pilt
  • Formaat: PDF+DRM
  • Ilmumisaeg: 23-Jan-2014
  • Kirjastus: Cambridge University Press
  • Keel: eng
  • ISBN-13: 9781107722736
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"Get up to speed with digital holography with this concise and straightforward introduction to modern techniques and conventions. Building up from the basic principles of optics, this book describes key techniques in digital holography, such as phase-shifting holography, low-coherence holography, diffraction tomographic holography and optical scanning holography, discussing their practical applications, and accompanied by all the theory necessary to understand the underlying principles at work. A furtherchapter covers advanced techniques for producing computer-generated holograms. Extensive Matlab code is integrated with the text throughout and available for download online, illustrating both theoretical results and practical considerations such as aliasing, zero padding and sampling. Accompanied by end-of-chapter problems and an online solutions manual for instructors, this is an indispensable resource for students, researchers and engineers in the fields of optical image processing and digital holography"--

Muu info

Get up to speed with digital holography with this compact and straightforward introduction to modern techniques and conventions.
Preface ix
1 Wave optics 1(26)
1.1 Maxwell's equations and the wave equation
1(2)
1.2 Plane waves and spherical waves
3(2)
1.3 Scalar diffraction theory
5(9)
1.3.1 Fresnel diffraction
9(2)
1.3.2 Fraunhofer diffraction
11(3)
1.4 Ideal thin lens as an optical Fourier transformer
14(1)
1.5 Optical image processing
15(9)
Problems
24(2)
References
26(1)
2 Fundamentals of holography 27(32)
2.1 Photography and holography
27(1)
2.2 Hologram as a collection of Fresnel zone plates
28(5)
2.3 Three-dimensional holographic imaging
33(9)
2.3.1 Holographic magnifications
38(1)
2.3.2 Translational distortion
39(1)
2.3.3 Chromatic aberration
40(2)
2.4 Temporal and spatial coherence
42(14)
2.4 1 Temporal coherence
43(2)
2.4.2 Coherence time and coherence length
45(1)
2.4.3 Some general temporal coherence considerations
46(2)
2.4.4 Fourier transform spectroscopy
48(3)
2.4.5 Spatial coherence
51(2)
2.4.6 Some general spatial coherence considerations
53(3)
Problems
56(2)
References
58(1)
3 Types of holograms 59(20)
3.1 Gabor hologram and on-axis (in-line) holography
59(2)
3.2 Off-axis holography
61(3)
3.3 Image hologram
64(4)
3.4 Fresnel and Fourier holograms
68(5)
3.4.1 Fresnel hologram and Fourier hologram
68(2)
3.4.2 Lensless Fourier hologram
70(3)
3.5 Rainbow hologram
73(5)
Problems
78(1)
References
78(1)
4 Conventional digital holography 79(39)
4.1 Sampled signal and discrete Fourier transform
79(10)
4.2 Recording and limitations of the image sensor
89(6)
4.2.1 Imager size
91(1)
4.2.2 Pixel pitch
91(1)
4.2.3 Modulation transfer function
92(3)
4.3 Digital calculations of scalar diffraction
95(10)
4.3.1 Angular spectrum method (ASM)
95(2)
4.3.2 Validity of the angular spectrum method
97(2)
4.3.3 Fresnel diffraction method (FDM)
99(2)
4.3.4 Validation of the Fresnel diffraction method
101(2)
4.3.5 Backward propagation
103(2)
4.4 Optical recording of digital holograms
105(6)
4.4.1 Recording geometry
105(3)
4.4.2 Removal of the twin image and the zeroth-order light
108(3)
4.5 Simulations of holographic recording and reconstruction
111(5)
Problems
116(1)
References
117(1)
5 Digital holography: special techniques 118(33)
5.1 Phase-shifting digital holography
118(8)
5.1.1 Four-step phase-shifting holography
119(1)
5.1.2 Three-step phase-shifting holography
120(1)
5.1.3 Two-step phase-shifting holography
120(2)
5.1.4 Phase step and phase error
122(2)
5.1.5 Parallel phase-shifting holography
124(2)
5.2 Low-coherence digital holography
126(7)
5.3 Diffraction tomographic holography
133(4)
5.4 Optical scanning holography
137(10)
5.4.1 Fundamental principles
138(4)
5.4.2 Hologram construction and reconstruction
142(2)
5.4.3 Intuition on optical scanning holography
144(3)
Problems
147(1)
References
148(3)
6 Applications in digital holography 151(28)
6.1 Holographic microscopy
151(7)
6.1.1 Microscope-based digital holographic microscopy
151(3)
6.1.2 Fourier-based digital holographic microscopy
154(2)
6.1.3 Spherical-reference-based digital holographic microscopy
156(2)
6.2 Sectioning in holography
158(6)
6.3 Phase extraction
164(4)
6.4 Optical contouring and deformation measurement
168(7)
6.4.1 Two-wavelength contouring
169(3)
6.4.2 Two-illumination contouring
172(3)
6.4.3 Deformation measurement
175(1)
Problems
175(1)
References
175(4)
7 Computer-generated holography 179(35)
7.1 The detour-phase hologram
179(6)
7.2 The kinoform hologram
185(2)
7.3 Iterative Fourier transform algorithm
187(2)
7.4 Modern approach for fast calculations and holographic information processing
189(10)
7.4.1 Modern approach for fast calculations
189(7)
7.4.2 Holographic information processing
196(3)
7.5 Three-dimensional holographic display using spatial light modulators
199(11)
7.5.1 Resolution
199(2)
7.5.2 Digital mask programmable hologram
201(4)
7.5.3 Real-time display
205(1)
7.5.4 Lack of SLMs capable of displaying a complex function
206(4)
Problems
210(1)
References
211(3)
Index 214
Ting-Chung Poon is a Professor of Electrical and Computer Engineering at Virginia Tech, and a Visiting Professor at the Shanghai Institute of Optics and Fine Mechanics, Chinese Academy of Sciences. He is a Fellow of the OSA and SPIE. Jung-Ping Liu is an Associate Professor in the Department of Photonics at Feng Chia University, Taiwan.
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