Program code: 11.03.01
The key to the science and technology advancement is the acceleration of information exchange. Today it can only be achieved through the use of electromagnetic phenomena.
Future radio engineers study modern computer-aided design, circuit design and electronics, micro-controller technology, and also get skills by using modern electronic equipment, using computer-aided design of radio equipment.
The graduates of this program complete their basic radio engineering education with the knowledge in development and operation of modern radio and broadcasting devices (satellite, wireless phones, microwave, paging, cellular systems), creation of networks, and microprocessor technologies. Their studies are focused on systematical training of students (network and data communications, networking and protocols), digital methods and devices of transmission, reception and processing of information, its protection from unauthorized access, microwave equipment, design and programming of telecommunications equipment.
Master degree
After obtaining their Bachelor degree, students can continue their studies with the “Radio engineering” Master degree program.
Participation in real projects
TUSUR University allows students to take part in Project Based Group Learning (PBGL). Students at " Radiotechnical Means for Transmission, Reception and Processing of Signals" participate in following development works:
Quantum cryption. Students work on the fiber optical channel for confidential data transmission with the quantum cryption technology. The project distinction is in the design of a new programming and circuit solutions to realize a technology of single-photon state temporal coding.
Radio-wave scanning. Development of a mathematical model for radio-wave scanning using radio interferential scan method.
Planar microwave antenna. Participants of the project perform the calculation, computer modeling and design of broadband dual-polarization printed UHF antenna for various applications. The development is made within the Cooperation agreement between TUSUR university and JSC "SPC" Micran. '"
Future radio engineers study modern computer-aided design, circuit design and electronics, micro-controller technology, and also get skills by using modern electronic equipment, using computer-aided design of radio equipment.
The graduates of this program complete their basic radio engineering education with the knowledge of development and operation of modern antennas and microwave-spectrum devices for radio connection and broadcasting (satellite, wireless, radio-relay and cellular systems). Their studies are focused on network and data communications, networking and protocols, design of antennas and transmitting devices, microwave data reception and processing equipment, design and programming for telecommunications equipment.
Master degree
After obtaining their Bachelor degree, students can continue their studies with the “Microwave Equipment and Antennas” or “Radio Engineering” Master degree programs.
Participation in real projects
TUSUR University allows students to take part in Project Based Group Learning (PBGL). Students at "Microwave Equipment and Antennas" participate in following development works:
Power characteristics measurement of microwave signals. Students develop instrumentation required to measure several power parameters. It is planned to manufacture prototypes and prepare the mass production of devices at the facilities of JSC "SPC" Micran'".
Planar microwave antenna. Participants of the project perform the calculation, computer modeling and design of broadband dual-polarization printed UHF antenna for various applications. The development is made within the Cooperation agreement between TUSUR university and JSC "SPC" "Micran."
Development of an integrated circuit for GIS receiver. Students participate in the development of a modern satellite system, which is equipped with autonomous navigation system that uses global positioning systems signals to determine the coordinates of the satellite in space without ground-based radio-tracking. This increases the independence and reliability of the satellite. For good accuracy of the coordinates, the system shall receive signals from the largest possible number of satellites. The weight of the system is another important factor, that is why the integrated technologies are used.
Electromagnetic compatibility means the ability of a device to function in its electromagnetic environment without interfering with other devices. Industry is becoming increasingly reliant on technology and devices based on the latest advances of electrical engineering and radio engineering. No person today can go without a TV, phone, PC and other devices that are becoming ever more diverse, complex, and that interfere with one another. As devices are becoming more sophisticated, their susceptibility to interference increases, highlighting the problem of electromagnetic compatibility.
Electromagnetic compatibility professionals can assess vulnerabilities and identify channels of intentional and unintentional interferences, select and use the best technology solutions to improve interference resistance, reduce time and funding required for engineering projects, study and design protection and testing tools, as well as specialized mathematical software for simulation.
Students pursuing a degree in Electromagnetic Compatibility study the engineering solutions for interference protection, learn to work with technical rules and regulations, measuring devices and testing equipment, study programming languages and simulate electromagnetic compatibility programs, develop software and design protection devise and testing equipment.
Master degree
A Bachelor graduate may choose to pursue a postgraduate degree with a focus on Electromagnetic Compatibility of Electromagnetic Equipment, Electromagnetic Compatibility in Fuel and Energy Sector and Protection from Electromagnetic Terrorism.
Participation in real projects
Students will have a chance to contribute to R&D projects carried out by the Security and Electromagnetic Compatibility of Radio Electronic Devices Laboratory:
Interference protection of power bus lines on spacecraft. The project is developing a software/hardware complex for design of interference-free power bus lines for spacecraft for Information Satellite Systems Reshetnev.
Design of equipment for electromagnetic compatibility testing. Development of new testing devices, including one-of-a-kind devices for joint climate and electromagnetism tests.
Computational electromagnetic compatibility. Design of algorithms and subprograms for the national system for computer-aided simulation of electromagnetic compatibility.
Learn more about the activities of our students on talgat.org.