Introduction to modern digital holography : with MATLAB /
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| Author / Creator: | Poon, Ting-Chung. |
|---|---|
| Imprint: | Cambridge [England], United Kingdom : Cambridge University Press, 2014. |
| Description: | 1 online resource |
| Language: | English |
| Subject: | |
| Format: | E-Resource Book |
| URL for this record: | http://pi.lib.uchicago.edu/1001/cat/bib/12014862 |
Table of Contents:
- Cover; Half title; Title; Copyright; Contents; Preface; 1 Wave optics; 1.1 Maxwell's equations and the wave equation; 1.2 Plane waves and spherical waves; 1.3 Scalar diffraction theory; 1.3.1 Fresnel diffraction; 1.3.2 Fraunhofer diffraction; 1.4 Ideal thin lens as an optical Fourier transformer; 1.5 Optical image processing; Problems; References; 2 Fundamentals of holography; 2.1 Photography and holography; 2.2 Hologram as a collection of Fresnel zone plates; 2.3 Three-dimensional holographic imaging; 2.3.1 Holographic magnifications; 2.3.2 Translational distortion.
- Example 2.1: Holographic magnification2.3.3 Chromatic aberration; Example 2.2: Chromatic aberration calculation; 2.4 Temporal and spatial coherence; 2.4.1 Temporal coherence; 2.4.2 Coherence time and coherence length; 2.4.3 Some general temporal coherence considerations; 2.4.4 Fourier transform spectroscopy; 2.4.5 Spatial coherence; 2.4.6 Some general spatial coherence considerations; Example 2.3: Double-pinhole interference; Problems; References; 3 Types of holograms; 3.1 Gabor hologram and on-axis (in-line) holography; 3.2 Off-axis holography.
- Example 3.1: Determination of the offset angle and the required resolving power of the recording medium3.3 Image hologram; Example 3.2: Simulation of an image hologram; 3.4 Fresnel and Fourier holograms; 3.4.1 Fresnel hologram and Fourier hologram; Example 3.3: Simulation of a Fourier transform hologram; 3.4.2 Lensless Fourier hologram; 3.5 Rainbow hologram; Example 3.4: Simulation of a rainbow hologram simulation; Problems; References; 4 Conventional digital holography; 4.1 Sampled signal and discrete Fourier transform; Example 4.1: Under-sampling and aliasing; Example 4.2: Sampling.
- Example 4.3: Fourier transform of a rectangular function4.2 Recording and limitations of the image sensor; 4.2.1 Imager size; 4.2.2 Pixel pitch; 4.2.3 Modulation transfer function; 4.3 Digital calculations of scalar diffraction; 4.3.1 Angular spectrum method (ASM); Example 4.4: Diffraction of a rectangular aperture; 4.3.2 Validity of the angular spectrum method; 4.3.3 Fresnel diffraction method (FDM); 4.3.4 Validation of the Fresnel diffraction method; Example 4.5: Diffraction of a rectangular aperture (using FDM); 4.3.5 Backward propagation; 4.4 Optical recording of digital holograms.
- 4.4.1 Recording geometryOn-axis Fresnel holography; Off-axis Fresnel holography; Fourier holography; 4.4.2 Removal of the twin image and the zeroth-order light; Fourier holography; Off-axis Fresnel holography; Example 4.6: Recording an off-axis digital hologram; 4.5 Simulations of holographic recording and reconstruction; Example 4.7: Simulation of on-axis holographic recording and reconstruction; Example 4.8: Simulation of off-axis holographic recording and reconstruction; Problems; References; 5 Digital holography: special techniques; 5.1 Phase-shifting digital holography.