Mathematics for telecommuications
| Code | Completion | Credits | Range | Language |
|---|---|---|---|---|
| XD01MTR | Z,ZK | 6 | 19+4 | Czech |
- Prerequisite:
- Mathematics 3B (XD01M3B)
- Lecturer:
- Tutor:
- Supervisor:
- Department of Mathematics
- Synopsis:
-
The course covers various mathematical topics for radio technique and telecomunication, in particular: Matrix theory (eigenvectors, spectral decomposition), Integral transform (Fourier, Laplace and Z-transform), Special functions.
- Requirements:
-
The requirement for receiving the credit is an active participation in the tutorials.
- Syllabus of lectures:
-
1. Laurent series and Fourier series in complex field. Singularity and residua
2. Fourier transform. Inverse Fourier transform
3. Complex Laplace transform, image of periodic function and power series
4. Inverse Laplace transform (ILT). Inverse image of rational function
5. Integral form of ILT. Residua method.
6. Z-transform, basic properties
7. Finding inverse Z-transform by means of residua. Difference equations
8. Gamma and Beta function in the complex field
9. Bessel functions, application to wave equation
10. Eigenvalues and eigenvectors of matrices. Hermitian, positive and unitary matrices
11. Spectral resolution of the matrix
12. Function calculus for matrices. Linear equations with sparse matrix.
13. Numerical solution of the system of nonlinear equations -- Newton method
14. Partial differential equation -- boundary condition
- Syllabus of tutorials:
-
1. Laurent series and Fourier series in complex field. Singularity and residua
2. Fourier transform. Inverse Fourier transform
3. Complex Laplace transform, image of periodic function and power series
4. Inverse Laplace transform (ILT). Inverse image of rational function
5. Integral form of ILT. Residua method.
6. Z-transform, basic properties
7. Finding inverse Z-transform by means of residua. Difference equations
8. Gamma and Beta function in the complex field
9. Bessel functions, application to wave equation
10. Eigenvalues and eigenvectors of matrices. Hermitian, positive and unitary matrices
11. Spectral resolution of the matrix
12. Function calculus for matrices. Linear equations with sparse matrix.
13. Numerical solution of the system of nonlinear equations -- Newton method
14. Partial differential equation -- boundary condition
- Study Objective:
- Study materials:
-
1. There is no text-book covering the course completely. The lecturer will hint resources to particular topics.
- Note:
- Further information:
- No time-table has been prepared for this course
- The course is a part of the following study plans:
-
- Telecommunications and Radio-engineering - High-frequency and Microwave Technology- structured studi (compulsory course)
- Telecommunications and Radio-engineering - Opto-electric Systems- structured studies (compulsory course)
- Telecommunications and Radio-engineering - Radio Communications, Navigation and Radar Systems- struc (compulsory course)
- Telecommunications and Radio-engineering - Multimedia, Sound and Television Technology- structured s (compulsory course)
- Telecommunications and Radio-engineering - Telecommunications- structured studies (compulsory course)