Image Photonics
Code | Completion | Credits | Range | Language |
---|---|---|---|---|
B2M37OBF | Z,ZK | 5 | 2P+2L | Czech |
- Garant předmětu:
- Lecturer:
- Tutor:
- Supervisor:
- Department of Radioelectronics
- Synopsis:
-
The subject offers a detailed overview of applied imaging photonic elements and systems. The subject deals with fundamentals of optics, Fourier optics and optical computing. Fourier optics. Image sensors - tube, CCD, CMOS. Image displays. Image converters and amplifiers. Photography and holography - sensitometry and densitometry. Photonic (optical) computing. Electron optics. Image processing in biosystems. Image processing for photonics.
- Requirements:
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Knowledge of physics, mathematical analysis, and analysis of signals and systems.
- Syllabus of lectures:
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1. Introduction - basic principles of image photonics
2. Geometrical optics
3. Imaging systems - design, construction, types, applications, measurements
4. Photometry, radiometry, colorimetry - basic formulae, applications, illumination
5. Fourier optics - subsystems, matrix optics - description of optical systems
5. Image sensors I. - tubes, switched arrays of photoelements (CMOS etc.), termovision
6. Image sensors II. - CCD image sensors - properties and modifications
7. Image displays - picture tubes, LED and laser diode arrays, LCD, plasma, DMD
8. Image converters and amplifiers - special applications (night vision, X ray systems)
9. Photography, holography, polygraphy - physical principles, sensitometry, densitometry
10. Optical (photonic) processors - 2D FT, 2D correlation, filtration, algebraic processors
11. Electron optics for imaging - elst and mg lenses, types of electron guns
12. Image processing in biological systems - analogy with optical systems
13. Image processing in photonics - compensation of real properties of sensors and displays
14. Conclusion, summary and future trends overview
- Syllabus of tutorials:
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1. Introduction, organization and content of labs, working groups
2. Laboratory experiments - explanation (Camera MTF, Optical 2D FT, Image sensors)
3. MTF of TV camera - transmission function of optical system, impact of objective
4. Optical 2D Fourier transform - 2D spatial analysis and filtering
5. Image sensors - spectral and temporal characteristics, sensing aperture
6. Test
7. Laboratory experiments - explanation (Image displays, Electron optics, Illumination)
8. Image displays - spectral and temporal characteristics, color fidelity
9. Electron optics - electron motion in elst and mg fields, imaging systems
10. Illumination - design of illumination system, color temperature
11. Test
12. Computer simulation - aperture distortion, spectral and spatial representation
13. Colloquium - discussion of theoretical parts, examples
14. Conclusion, evaluation and assessment
- Study Objective:
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Students learn principles and methods of image photonics, optics (geometrical, wave and Fourier) and advances in image recording and optical computing.
- Study materials:
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[1] Saleh, B.E.A., Teich, M.C.: Základy fotoniky. (4 svazky), Matfyzpress, Praha 1994-1996
[2] B. Jahne, Image Processing for Scientific Applications, CRC, New York, 1997.
[3] J. W. Goodman, Introduction to Fourier Optics, 3rd edition, Roberts&Company Pub., 2005
- Note:
- Further information:
- https://moodle.fel.cvut.cz/courses/B2M37OBF
- No time-table has been prepared for this course
- The course is a part of the following study plans:
In order to register for the course B2M37OBF, the student must have registered for the required number of courses in the group BEZBM no later than in the same semester.
The requirement for course B2M37OBF can be fulfilled by substitution with the course B2M37OBFA.