English

Not applicable.

The graduate is able to: (1) describe the common telecommunication system architecture, (2) explain the basic building blocks operation, (3) characterize the transmission media and influences of the transmission environment, (4) explain the methods of signal processing in the sub-parts of the system, (5) discuss the signal processing techniques in specific systems.

Knowledge of bachelor mathematics (integral calculus, solution of equations, fundamentals of probability analysis and statistics), fundamentals of signal processing (convolution, correlation, filtering, spectrum analysis), and fundamentals of communications (see BPA-KSY or equivalent) are requested.

Not applicable.

Teaching methods depend on the type of course unit as specified in the article 7 of BUT Rules for Studies and Examinations.

Students can obtain maximally 30 points for their activities during semester and 70 points for the final exam. The honored activities are as follows: one midterm test oriented to the application of selected signal processing techniques (10 points) and laboratory measurements (20 points). The written final exam is based on the theory as well as calculations (70 points).

Lectures:
1. Digital telecommunication system common architecture, basic building blocks.
2. Formatting and source coding. Sampling of bandpass signals, quantization.
3. Cryptography, conventional and public key cryptosystem. RSA encryption. Authentication.
4. Channel coding. Block and convolutional codes, concatenated codes, RS, BCH, turbo and LDPC codes.
5. Detection of communication signals in noise. Binary signal reception, matched filter. Line codes.
6. Inter-symbol interference. Impulse shaping. Signal equalization (zero forcing, MMSE).
7. Band-pass modulation (MPSK, MSK, GMSK, MQAM). False detection probability. Trellis-coded modulation.
8. Communication channel (metallic line, optical fiber, free space). Noise and fading channel.
9. Carrier frequency and phase synchronization. Symbol, frame and network synchronization.
10. Wireless networks, satellite communications, link power budget, transmission capacity allocation.
11. Structure of DAB, DMB, DRM, DVB, IEEE 802.11, PHY, and MAC layers.
12. Communication in computer and telecommunication networks in terms of the reference model ISO/OSI.
13. Computer networks, access methods, routing, networking.

Not applicable.

The aim of course is to introduce the structure of telecommunication systems, the characteristics of the transmission environment and the methods of signal processing in the sub-blocks of this system.

Laboratory exercises are compulsory. Missed lessons can be made up usually by the end of semester.

Not applicable.

Not applicable.

COUCH, L.V. Digital and analog Communications. Upper Saddle River: Prentice Hall, 2001. (EN)
DUNLOP, J., SMITH, D.G. Telecommunications Engineering, CRC Press, 1994. (EN)
SKLAR, B. Digital Communications: Fundamental and Applications, 3rd Edition. Pearson, 2020. (EN)

Not applicable.