Imaging Photonics
| Code | Completion | Credits | Range | Language |
|---|---|---|---|---|
| X37OBF | Z,ZK | 5 | 2+2s | Czech |
- Lecturer:
- Tutor:
- Supervisor:
- Department of Radioelectronics
- Synopsis:
-
Imaging systems. Photometry, radiometry and colorimetry. 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. The subject offers a detailed overview of applied imaging photonic elements and systems.
- Requirements:
- Syllabus of lectures:
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1. Introduction
2. Imaging systems - design, construction, types, applications, measurements
3. Photometry, radiometry, colorimetry - basic formulae, applications, illumination
4. 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:
- Study materials:
-
1. Smith, F. G.: Optics and Photonics. An Introduction. John Wiley. 2000
- Note:
- Further information:
- No time-table has been prepared for this course
- The course is a part of the following study plans: