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17ADBOMTB - Optical methods, technology and instruments for biomedicine

Code Completion Credits Range Language
17ADBOMTB ZK 5 2P English
Lecturer:
Tutor:
Supervisor:
Department of Natural Sciences
Synopsis:

1) Physical description of optical wave fields. Sources and detectors of optical radiation. 2) Description and modeling of transport of energy. Interaction of light with matter. 3) Diffraction and theory of optical imaging. Aberrations of optical systems. 4) Analysis and modeling of optical systems. Basics of optical design for imaging, diagnostics, and measurements in biomedicine. 5) Design of selected imaging and diagnostic optical systems in biomedical instruments and methods. 6) Polarization properties of optical systems and their measurements. 7) Basics of crystal optics. Liquid crystals. 8) Radiometric, photometric and spectral properties of optical systems. 9) Technology of active and adaptive optics.10) Technology of diffractive optics. 11) Technology of gradient index optics. 12) Basics of nonlinear optics, electro-optics, magneto-optics, acousto-optics, photo-acoustics. 13) Physical principles of selected optical and optoelectronic instruments in biomedicine. 14) Present technologies of production and metrology of classical and non-classical optics

Requirements:

Teaching is performed in the form of the controlled self-study with regular consultations. Except for the examination the student is required to write an extra study on a given topic.

Syllabus of lectures:

1) Physical description of optical wave fields. Sources and detectors of optical radiation. 2) Description and modeling of transport of energy. Interaction of light with matter. 3) Diffraction and theory of optical imaging. Aberrations of optical systems. 4) Analysis and modeling of optical systems. Basics of optical design for imaging, diagnostics, and measurements in biomedicine. 5) Design of selected imaging and diagnostic optical systems in biomedical instruments and methods. 6) Polarization properties of optical systems and their measurements. 7) Basics of crystal optics. Liquid crystals. 8) Radiometric, photometric and spectral properties of optical systems. 9) Technology of active and adaptive optics.10) Technology of diffractive optics. 11) Technology of gradient index optics. 12) Basics of nonlinear optics, electro-optics, magneto-optics, acousto-optics, photo-acoustics. 13) Physical principles of selected optical and optoelectronic instruments in biomedicine. 14) Present technologies of production and metrology of classical and non-classical optics.

Syllabus of tutorials:
Study Objective:
Study materials:

Required:

[1] A.Mikš: Aplikovaná optika. Vydavatelství ČVUT, Praha 2009.

[2] B. E. A. Saleh, M. C. Teich: Fundamentals of Photonics, Wiley 2007.

Recommended:

[3] M.Bass: Handbook of Optics. Vol.I-V, McGraw-Hill Professional, 2009.

[4] H. Gross (ed.): Handbook of Optical Systems. Vol.I-V, Wiley-VCH, 2008.

[5] J.Fujimoto, D.Farkas: Biomedical Optical Imaging. Oxford University Press, 2009.

[6] R.Splinter, B.Hooper: An Introduction to Biomedical Optics. CRC Press, 2006.

[7] R.Liang: Biomedical Optical Imaging Technologies. Springer 2013.

[8] R.Liang: Optical Design for Biomedical Imaging. SPIE Press 2010.

[9] B.C.Kress, P.Meyrueis: Applied Digital Optics: From Micro-optics to Nanophotonics. Wiley 2009.

Note:
The course is a part of the following study plans:
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