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Lecturer(s)
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Hrabovský Miroslav, prof. RNDr. DrSc.
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Course content
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- Basics of wave theory and theory of coherence - Principle of optical holography, types of holograms and their characteristics, classification of methods of recording and reconstruction of holograms - Principle of holographic interferometry, hologram recording and reconstruction - Recording materials, their types and properties - Methods of qualitative and quantitative evaluation of holographic interferograms, phase and absorption objects - Spatial filtration - Localization of interference fringes - Holographic memories - Applications: measurement of components of deformation tensor and related quantities, nondestructive holographic materiology - Applications in aeromechanics and hydromechanics, visualization of the flow and holographic interferometry, analysis of the mechanical stress in mechanics, application in biomechanics - Optical correlation and correlators
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Learning activities and teaching methods
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Dialogic Lecture (Discussion, Dialog, Brainstorming)
- Preparation for the Exam
- 600 hours per semester
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Learning outcomes
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The aim is to give students information about theory of holography and holographic interferometry.
Knowledge Show knowledge of terminology of holography and holographic interferometry, show knowledge of optical principles, methodology and experimental realization of methods of holographic recording and reconstruction.
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Prerequisites
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Basic knowledge of the undergraduate physics.
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Assessment methods and criteria
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Oral exam
Knowledge within the scope of the course topics (examination)
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Recommended literature
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Abramson, N. (1996). Light in Flight on the Holodiagram. SPIE Opt. Eng. Press, SPIE - Belingham, Washington.
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Mehta, P. C. Rampal, V. V. (1993). Lasers and Holography. World Scientific, London.
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West, Ch. M. (1994). John Wiley & Sons Inc., New York, 1979. [Ed. by RASTOGI P. K.: Holographic Interferometry. Principles and Methods. Springer-Verlag, Berlin.
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