Download PDF OPTICAL SCANNING HOLOGRAPHY WITH MATLAB by TING-CHUNG POON

Sinopsis

Optical Scanning Holography with MATLAB® consists of tutorials (with numerous MATLAB examples throughout the text), research material, as well as new ideas and insights that are useful for engineering or physics students, scientists, and engineers working in the fields of Fourier optics, optical scanning imaging and holography. The book is self-contained and covers the basic principles of OSH. Thus, this book will be relevant for years to come. The writing style of this book is geared towards undergraduate seniors or first-year graduate-level students in the fields of engineering and physics. The material covered in this book is suitable for a one-semester course in Fourier optics, optical scanning imaging and holography.

Optical scanning holography is a highly sophisticated technology that consists of numerous facets and applications. It is a real-time (or on-the-fly) holographic recording technique that is based on active optical heterodyne scanning. It is a relatively new area in electronic holography and will potentially lead science and technology to many novel applications such as cryptography, 3-D display, scanning holographic microscopy, 3-D pattern recognition and 3-D optical remote sensing. The main purpose of this book is to introduce optical scanning holography to the readers in a manner that will allow them to feel comfortable enough to explore the technology on their own - possibly even encourage them to begin implementing their own set-ups in order to create novel OSH applications. Optical scanning holography is generally a simple yet powerful technique for 3-D imaging, and it is my aspiration that this book will stimulate further research of optical scanning holography and its various novel applications.

Content

1. Mathematical Background and Linear System
2. Fourier Transformation
3. Linear and Invariant Systems
4. Linearity and Invariance
5. Convolution and Correlation Concept
6. Wave Optics and Holography
7. Maxwell’s Equations and Homogeneous Vector Wave Equation
8. Three-Dimensional Scalar Wave Equation
9. Plane Wave Solution
10. Spherical Wave Solution
11. Scalar Diffraction Theory
12. Fresnel Diffraction
13. Diffraction of a Square Aperture
14. Ideal Lens, Imaging Systems, Pupil Functions and Transfer Functions
15. Ideal Lens and Optical Fourier Transformation
16. Coherent Image Processing
17. Incoherent Image Processing
18. Holography
19. Fresnel Zone Plate as a Point-Source Hologram
20. Off-Axis Holography
21. Digital Holography
22. Optical Scanning Holography: Principles
23. Principle of Optical Scanning
24. Optical Heterodyning
25. Acousto-Optic Frequency Shifting
26. Two-Pupil Optical Heterodyne Scanning Image Processor
27. Scanning Holography
28. Physical Intuition to Optical Scanning Holography
29. Optical Scanning Holography: Applications
30. Scanning Holographic Microscopy
31. Three-Dimensional Holographic TV and 3-D Display
32. Optical Scanning Cryptography
33. Optical Scanning Holography: Advances
34. Coherent and Incoherent Holographic Processing
35. Single-Beam Scanning vs. Double-Beam Scanning
36. PSF Engineering

Click here to download