will be practically verified in the design of selected optical components based on thin layers.
1. Electromagnetic optics, Maxwell's equations, solution of the wave equation in an isotropic medium
2. Thin film interference
3. Periodic systems of thin films, Bragg mirror
4. Berreman approach to solving Maxwell's equations
5. Solutions for general anisotropy environments
6. Boundary conditions - continuity of fields at the interface, description of optical response using T and S-matrix
7. Ellipsometric angles, Mueller matrices
8. Modelling the optical response of layered structures
9. Optical data processing and fitting, reflectance, transmittance, ellipsometry
10. Task: Design and optimization of 1D photonic crystal structure for selected input parameters
11. Practical task: Design of polarization beam splitter
12. Practical Task: Design of a spectral filter
13. Practical task: Narrowband filter design
1. Electromagnetic optics, Maxwell's equations, solution of the wave equation in an isotropic medium
2. Thin film interference
3. Periodic systems of thin films, Bragg mirror
4. Berreman approach to solving Maxwell's equations
5. Solutions for general anisotropy environments
6. Boundary conditions - continuity of fields at the interface, description of optical response using T and S-matrix
7. Ellipsometric angles, Mueller matrices
8. Modelling the optical response of layered structures
9. Optical data processing and fitting, reflectance, transmittance, ellipsometry
10. Task: Design and optimization of 1D photonic crystal structure for selected input parameters
11. Practical task: Design of polarization beam splitter
12. Practical Task: Design of a spectral filter
13. Practical task: Narrowband filter design