11.03.04 Electronics and Nanoelectronics

The "Industrial Electronics" profile offers a dynamic and challenging program designed to train highly skilled professionals capable of shaping the future of electronics in a wide range of industries.

This program provides a comprehensive understanding of the fundamental principles of:

• Power Electronics: Explore the design and application of power electronic circuits and devices, including inverters, converters, and rectifiers, essential for efficient energy conversion and control.
• Electrical Engineering: Develop a strong foundation in electrical engineering principles, including circuit analysis, power systems, and electromagnetic theory.
• Microprocessor Control Systems: Master the design and implementation of microprocessor-based control systems for industrial applications, enabling intelligent automation and optimization.
• Programming and Microelectronics: Gain proficiency in programming languages and microelectronics, enabling you to develop and implement embedded systems and control algorithms.
• Power Engineering and Electric Drive: Explore the principles of power engineering, including electric drives, power systems, and electric machines, enabling you to design and implement efficient and reliable power systems.

The Department of Electronics and Electrical Engineering boasts the Institute of Power Electronics (IPE), dedicated to real-world research and development for industrial applications. By joining this program, students gain access to cutting-edge facilities and collaborate on impactful projects, preparing them for rewarding careers.

State-of-the-art laboratories equipped with advanced technology provide students with valuable practical experience in:

• Analog and Digital Circuit Design: Develop skills in designing and implementing both analog and digital circuits.
• Power Semiconductor Devices: Gain a deep understanding of the operation and design of power semiconductor devices used in a wide range of applications.
• Microprocessor Technology: Master the principles and applications of microprocessors and microcontrollers in control systems.
• Power Electronics Modeling and Simulation: Develop proficiency in modeling and simulating power electronic systems using advanced software tools.

• Information technologies in professional activity
• Information technologies and programming basics
• Methods of analysis and calculation of electronic circuits
• Methods of mathematical modeling of electronics devices
• Metrology, standardization and certification
• Microelectronics
• Fundamentals of microprocessor technology
• Fundamentals of power electronics device design
• Fundamentals of power electronics
• Fundamentals of electromagnetic field theory
• Fundamentals of electric drive
• Software tools of professional activity
• Design activity
• Professional culture of engineer
• Power semiconductor devices
• Artificial Intelligence Systems and Machine Learning
• Circuit engineering
• Theoretical fundamentals of electrical engineering
• Digital and pulse circuitry
• Digital signal microcontrollers
• Elements of power electronics devices