23. Design of electronics, control and communication systems

Module Name:

Module 23. Design of electronics, control and communication systems

Code

M23REET(Ba)

Module Elements:

Elective Subjects

Antenna-Feeder Devices
Microwave Devices
Basic of Smart-City Hardware and Software System Design
Robotic Systems
Smart Technologies in Telecommunication
Networks and Systems
System Design based on Programmable Logic Integrated Circuits
Artificial Intelligence Systems
Electromagnetic Capability;
Radio Receivers

Compulsory Subjects

Work Experience Internship2      

Semester Number:

6

Person responsible for the module

D.V. Ritter

Lecturer:

Antenna-Feeder Devices – D.V. Ritter
MicrowaveDevices – P.A. Petrov
Basic of Smart-City Hardware and Software System Design – S.S. Moldakhmetov
Robotic Systems – P.A. Petrov
Smart Technologies in Telecommunication Networks and Systems – A.A. Savostin
System Design based on Programmable Logic Integrated Circuits – D.V. Ritter
Radio Receivers – P.A. Petrov Electromagnetic Capability – A.A. Savostin
Artificial Intelligence Systems – V.P. Kulikova
Work Experience Internship2 – T.I. Krashevskaya

Language: 

Russian, Kazakh 

Curriculum relation:

Radio Engineering, Electronics and Telecommunications (Ba)

Type of teaching  / number of hours per week and per semester : 

6 semester: hours per week – 24 (lectures -3; workshops -3; labs-3; independent work -15); Work Experience Internship 2 - 120 hours per semester – 480. 

Workload:

Teaching Load: 135 hours

Extracurricular Classes: 225 hours

Credit Points:

16 ECTS

Conditions for Examinations:

For admission to the exam, the student must score at least 50 points out of 100 available for the subject of the module

Recommended Conditions:

This module is based on the knowledge gained in the course of the following modules: Basics of Electrical Engineering, Design of Electronic Devices, Modules of modern electronic equipment 

Expected Learning Outcomes: 

Know: 

- methods of transmission, reception and processing of signals;

- technical methods for the creation (generation and formation) of electrical signals used in radio engineering for radio and television;

- models, types and varieties of antenna-feeder devices, features of modern radio transmission technologies;

- basic conceptual apparatus and the role of antenna-feeder devices in television, radio relay lines and communication; - principles of design and calculation of antenna-feeder devices;

- principles of construction of modern radio engineering and telecommunication systems;

- basic telecommunication technologies, types of equipment used in networks, signaling protocols of modern networks, principles of multiservice networks, principles of network management; 

- physical and mathematical models of processes and phenomena underlying the principles of radio engineering devices and systems;

- modern element base used for the construction of radio radio receivers;

- theoretical bases and principles of programming in radio electronics;

– basics of hardware and software development of modern automatic control systems;

-  classification of AIS, models of knowledge representation, output solutions and communication models in AIS; 

- structure and application of neural networks; 

- basic concepts of fuzzy sets;

-  principles of electromagnetic compatibility of technical means;

-  principles of construction of robotic systems; 

-  methods, levels and stages of design; algorithms for designing subsystems of robots.

Be able to: 

-  calculate antennas and microwave devices of different types; - conduct a full-scale experiment to measure the main indicators and properties of antenna-feeder devices;

-  adjust and install antennas and microwave devices;

– perform calculation and graphic works on design of information, electromechanical, electronic and microprocessor modules of hardware and robotic systems;

-  calculate the parameters of the schemes of radio receiving devices;

-   adjust and measure the basic electrical parameters of certain devices for receiving and processing of radio signals;

-  use measuring equipment for adjustment and testing of electronic devices;

-   use elements of fuzzy sets for mathematical formalization of initial information about the studied real situation or decisionmaking process;

-  assess the electromagnetic environment in the operation of technical means;

-  use special software for traffic analysis and network monitoring

Possess the skills:

- use software for end-to-end design of antenna-feeder devices;

- design of microwave units of electronic equipment;

– work with specialized software to create devices and robotic systems using sensors; 

-  modeling of hardware-software and robotic systems;

-  network fault detection and identification;

-   development technical, schematic and organizational activities for ensuring electromagnetic compatibility;

-  analysis of the functioning of certain units of modern equipment and devices;

Demonstrate the ability: 

-  to operate and maintain modern antenna-feeder devices; 

- to choose elements of antenna-waveguide equipment taking into account the requirements of miniaturization, reliability, electromagnetic compatibility, manufacturability, maintainability, ease of operation and economic efficiency;

- to evaluate various hardware and software and robotic systems for suitability for a specific task;

- to understand the wide range of problems associated with the use and prospects of using AIS;

- to interpret information on the network statistics;

- to administer the simplest network equipment. 

Intendend use/applicability

Modules: Modern Communication Systems 

Content:

Antenna-Feeder Devices

Basics of the theory of radio wave propagation. Types of antennas. Feeder devices. Calculation of the antenna radiation field. Antenna pattern. Antenna array. The radiation of the excited surfaces. VHF and HF antennas. Radio relay and satellite communication. Influence of the troposphere and ionosphere on the propagation of radio waves. Tropospheric communication lines.

Microwave Devices 

Microwave communication. Mobile networks of the latest generation. IEEE 802.11 standard. 802.15.4 standard. Wireless personal area network. Topology of a personal area network. ZigBee Alliance. Personal Bluetooth and Wi-fi networks. Prospects for the development of wireless networks.

Basic of Smart-City Hardware and Software System Design  Architecture and implementation of hardware and software systems of a Smart city. Modern hardware modules of automatic control systems.  Development and debugging of software for automatic control systems.

Robotic Systems 

System approach to the design of robotic systems. Design features of robotic systems. Simulation modeling of robots and robotic technological systems.

Smart Technologies in Telecommunication Networks and Systems  

Modern telecommunication technologies. Architecture of modern networks. Ethernet. IP-telephony. IPTV. NGN networks. Network management. TMN model.

System Design based on Programmable Logic Integrated Circuits

Design of digital systems. Programmable logic integrated circuits. Synthesis of combinational circuits on the PLD. Synthesis of finite state machines on SPLD. Synthesis of finite state machines on CPLD. Synthesis of programmable automata on PLD. Design of digital systems based on PLD.

Radio Receivers 

Technical properties of the radio. Classification of radio interference. High-frequency amplifiers, their purpose and properties. Ways to protect radios from interference.

Artificial Intelligence Systems

Mastering the principles of organization and functioning of AIS, as well as practical skills of their design, mastering systematic ideas about the possibilities and areas of use of AIS, their architectural features and means of their creation. Particular attention is paid to the study of methods of obtaining, formalization and structuring of problem knowledge and to storage and use of knowledge in knowledge bases. 

Electromagnetic Capability

Basic notions of electromagnetic compatibility. Sources of electromagnetic interference, their classification. Methods of description and presentation of interference. The way of interference penetration (parasitic channels).

Work Experience Internship2

Examination Form, module mark:

Comprehensive examination including

Antenna-Feeder Devices – free-form examination

Microwave Devices – free-form examination

Artificial Intelligence Systems – computer-based testing

Basic of Smart-City Hardware and Software System Design – computer-based testing

Robotic Systems – free-form examination

Smart Technologies in Telecommunication Networks and Systems  - written control examination

System Design based on Programmable Logic Integrated Circuits - computer-based testing

Radio Receivers – written control examination

Electromagnetic Capability - written control examination

Work Experience Internship2– internship report defense

Module mark: the result of the report defense

Work Experience Internship 2

Technical/Multimedia Facilities:

Multimedia system. Laboratory of Antenna-Feeder and Microwave Devices. Laboratory of Computer Mathematics and Electronic Simulation. Research laboratory of Robotics, Microelectronics and Energy Ecology. Laboratories of Radio Engineering Telecommunication Systems and Devices, Digital Communication Systems and Radio Receiving and transmitting Devices. 

Study Materials:

1. B. M. Petrov. Electrodynamics and Propagation Of Radio Waves: Textbook for universities. – M: Goryachaya liniya – Telekom, 2004. 
2. A. P. Kashkarov Modern Antennas. – M: Radiosoft, 2013.
3. Karl Rothammel. Antennas. – M: Layt-LTD, 2007.
4. D. I. Voskresenskiy, V. L. Gostyukhin, V. M. Maksimov, L. I. Ponomaryev. Microwave Devices and Antennas. Radiotechnics. – M: Akademiya, 2006.
5. V. I. Nazarov, V. I. Ryzhenko. All about Antennas. Reference book. – M.: ONIKS, 2008.
6. G. V. Savostina Methodical Guidelines for Professional Practice. – Petropavlovsk: NKSU named after M. Kozybayev, 2014.
7. Y. I. Yurevich. Basics of Robotics: Textbook, 2^nd ed. - SPb.: BHV-Petersburg, 2005. – 345 p. 
8. Y. A. Smirnov, S. V. Sokolov, Y. V. Titov. Basics of Microelectronics and Microprocessor Technology. Lan, 2013.
9. V. L. Afonin, V. A. Makushkin. Intelligent Robotic Systems. Internet University of Information Technologies, 2005 -208 p.
10. V. V. Krukhmalev, V. N. Gordiyenko, A. D. Mochenov. Digital Transmission Systems: Textbook for high schools / Under the editorship of A. D. Mochenov. - M.: Goryachaya liniya - Telekom, 2007.
11. Basics of Telecommunication Systems and Networks: Textbook for universities /V. V. Krukhmalev, V. N. Gordiyenko, A. D. Kochenov et al.; Under. editorship of V. N. Gordiyenko and V. V. Krukhmalev. - 2^nd ed., Rev. - M: Goryachaya liniya - Telekom, 2008.
12. V. N. Gordienko. Multichannel Telecommunication Systems: Textbook for high schools / V. N. Gordienko, M. S. Tveretskiy. - M.: GLT, 2013. – 396 p.
13. B. I. Kruk Telecommunication Systems and Networks. Textbook in 3 volumes. Volume 1 / B. I. Kruk. - M.: GLT, 2012. - 620 p
14. V. V. Solovyev. Logical Design of Digital Systems Based on Programmable Logic Integrated Circuits / Valeriy Vasilyevich Solovyev, Adam Klimovich. - M.: Goryachaya liniya - Telekom, 2014. – 376 p.
15. O. V. Golovin. Radio Receivers. – M: Goryachaya liniyaTelekom, 2004.
16. A.V. Veligosha. Devices for Receiving and Processing Radio Signals. – Stavropol: North Caucasus Federal University, 2014.
17. I. A. Bessmertniy. Artificial Intelligence Systems: Textbook for academic bachelors / I. A. Bessmertniy. – 2^nd ed., updated and revised. – M.: Yurayt, 2017. - 130 p. 
18. Y. Borovskaya. Basics of Artificial Intelligence / Y. Borovskaya. – M.: Binom, 2015. – 128 p.
19. M. V. Burakov. Artificial Intelligence Systems. Textbook / M. V. Burakov. – M.: Prospect, 2017. – 440 p.
20. Y. Y. Sedelnikov. Electromagnetic Capability of Radio Electronic Equipment. Textbook. - Kazan. ZAO Novoye znaniye, 2016.
21. M. P. Bader. Electromagnetic Capability. - M.: Transport, 2008. 

Date of last amendment

 20.01.2023