Course detail
Fourier Methods in Optics and in Structure Analysis
FSI-TFM Acad. year: 2019/2020 Summer semester
The course deals with the Fourier transform of functions of several variables and its use in diffraction theory and in structure analysis. The introductory parts are focused on the definition of the Fourier transform, spatial frequencies, spectrum of spatial frequencies and on the relevance of the Fourier transform to the diffraction theory. Then, the properties of the Fourier transform are presented via mathematical theorems and are illustrated by the Fraunhofer diffraction patterns. In this way a view of the general properties of the diffraction phenomena of this type is obtained. At the end the kinematical theory of diffraction by crystals is presented as an application of the Fourier transform of three-dimensional lattices. Analytical evaluation of the Fourier transform is exercised in tutorials and the Fraunhofer diffraction phenomena are registered by an optical diffractometer in the laboratory, and are interpreted in detail. The course puts accent on the common features of the diffraction in optics (two-dimensional objects) and in structure analysis (three-dimensional objects). Also emphasised are the common features of various methods of structure analysis (X-rays, neutrons, LEED, HEED). This way, the course provides a basis for activities in the Fourier optics and in various branches of structure analysis.
Language of instruction
Czech
Number of ECTS credits
4
Supervisor
Department
Learning outcomes of the course unit
The ability to calculate the Fourier transform. Knowledge of kinematical theory of diffraction in structure analysis. Ability to interpret the Fraunhofer diffraction phenomena in optics.
Prerequisites
Basic course of physics. Linear algebra. Calculus of functions of several variables.
Planned learning activities and teaching methods
The course is taught through lectures explaining the basic principles and theory of the discipline. Exercises are focused on practical topics presented in lectures.
Assesment methods and criteria linked to learning outcomes
Examination: Oral. Both practical and theoretical knowledge of the course is checked in detail. The examined student has 90 minutes to prepare the solution of the problems and he/she may use books and notes.
Aims
The aim of the course is to provide students with the formalism of the Fourier transform of functions of several variables as well as understanding of kinematical theory of diffraction in structure analysis and of the Fraunhofer diffraction in optics.
Specification of controlled education, way of implementation and compensation for absences
Course-unit credit is conditional on active participation in seminars. The way of compensation of missed lessons is specified by the teacher.
The study programmes with the given course
Programme N-FIN-P: Physical Engineering and Nanotechnology, Master's, elective
Programme B3A-P: Applied Sciences in Engineering, Bachelor's
branch B-FIN: Physical Engineering and Nanotechnology, elective (voluntary)
Programme M2A-P: Applied Sciences in Engineering, Master's
branch M-PMO: Precise Mechanics and Optics, compulsory
Type of course unit
Lecture
13 hours, optionally
Teacher / Lecturer
Syllabus
1. The Dirac distribution, its definition, properties and expressions in various coordinate systems. Examples.
2. The Fourier transform, definition, fundamental theorem. Examples. The diffraction of plane wave by a three-dimensional structure. The Ewald spherical surface.
3. The Fraunhofer diffraction as the Fourier transform of the transmission function. Meanings of variables in the Fourier transform. Spatial frequencies.
4. Linearity of the Fourier transform and the Babinet theorem. Examples. Rayleigh-Parseval theorem. Examples. Symmetry properties of the Fourier transform. Central symmetry, mirror symmetry, places of zero amplitude. The Friedel law.
5. The Fourier transform of functions related by regular linear transform of variables. Shift, rotation.
6. Convolution and the Fourier transform of convolution.
7. The Fourier transform of the function characterising a system of identical objects of the same orientation. Sampling theorem.
8. The Fourier transform of projection. The Abbe transform and the Abbe theorem.
9. Infinite lattice of points and its Fourier transform. The reciprocal lattice.
10. Infinite crystal lattice and its Fourier transform. The structure amplitude.
11. Finite lattice and its Fourier transform. Lattice amplitude and shape amplitude. Lattice amplitude as a sum of shape amplitudes.
12. Conditions of the principal diffraction maxima at the diffraction by lattices. The Laue equations and the Bragg equation.
13. Basic methods of structure analysis: X-ray diffraction, electron diffraction (LEED, HEED), neutron diffraction.
Exercise
26 hours, compulsory
Teacher / Lecturer
Syllabus
1. Examples of functions leading in the limit to the Dirac distribution.
2. Calculations of the Fourier transform.
3. Demonstration of the Fraunhofer diffraction phenomena in the laboratory.
4. The Fourier transform of the characteristic function of a parallelogram.
5. The function [sin(knaX/2)]/[sin(kaX/2)].
6. Demonstration of the Fraunhofer diffraction phenomena in the laboratory. The interpretation of the Fraunhofer diffraction phenomena.
7. The Fraunhofer diffraction by polygonal apertures.
8. The Fourier transform of the Fourier series.
9. The Fourier transform of the two-dimensional lattice. Interpretation of the Fraunhofer diffraction.
10. Calculation of the structure factors of body-centred, face-centred, diamond and h.c.p. structures.
11. Interpretation of the Debyegram of diamond.
12. Shape amplitudes of polyhedra, shapes of the diffraction spots at the diffraction by finite lattices, an illustration of the sampling theorem.