• ability to create computer models electrical systems dynamic using modern mathematical applications;
• the ability to choose the level of complexity of the mathematical model in accordance with the task;
• ability to study the behavior of typical electrical systems by means of computer modeling;
• ability to use modern computer and communication technologies, in particular Mathcad and MATLAB applications to solve problems of analysis of the controlled electromechanical systems dynamics.

• Control theory;
• Theory of electric drives;
• Electrical machines;
• Control systems for electric drives;
• Electromechanical control systems.

Mathematical and organizational principles of computer simulation. Analytical and numerical methods for solving the problems of electromechanical systems dynamics. Understanding the specifics of electrical systems mathematical models constructing, properties of numerical methods for solving problems of dynamics, the basis of object-oriented method for constructing computer models. Modern methods of mathematical models development. Application of the newest methods of digital models realization, application of neural networks, fuzzy logic and use of methods of thermodynamics. Modern means of computer simulation of electrical systems.

1. Костинюк Л.Д., Мороз В.І., Паранчук Я.С. Моделювання електроприводів. Львів: Видавництво Національного університету "Львівська політехніка". – 2004. – 404 с.
2. Зеленов А.В., Шевченко І.С., Андреева Н.І. Синтез та цифрове моделювання систем управління електроприводів постійного струму з вентильними перетворювачами. Навч. посібник для студ. вузів. – Алчевськ: ДГМІ, 2002. – 400 с.
3. Моделювання електромеханічних систем / Чорний О.П., Луговой А.В., Родькін Д.Й., Сисюк Г.Ю., Садовой О.В. – Кременчук, 2001. – 376 с.

• oral examination, laboratory reports (40%)
• final control: exam, written and oral form (60%)

• to know and understand scientific and mathematical principles required for solving of engineering problems in the field of electrical engineering;
• ability to choose proper methods and to simulate phenomena and processes in dynamical systems, and analyze obtained results;
• ability to apply obtained knowledge and skills for the solution of problems of synthesis and analysis of elements of electric systems typical for the specialty;
• ability to explain the choice of methods of specialized problems solving, critically evaluate the results obtained.

Prerequisites:
• Mathematical modeling of electrical engineering,
• Technique and electrophysics of high voltages;
• Electric networks and systems.

Mathematical bases of analysis of steady-state modes and transient processes in electric power systems, the question of mathematical modeling of wave processes in electric power systems, structural diagrams and frequency characteristics during the simulation of power systems, the basic concepts and methods of system identification, elements of the stability theory of electric power system and method of D-breaking.

1. Кириленко О.В., Сегеда М.С., Буткевич О.Ф., Мазур Т.А. Математичне моделювання в електроенергетиці: Підручник / – Львів: 2-е видання. Вид-во нац. ун-ту «Львівська політехніка», 2013. – 608 с.
2. Сегеда М.С. Електричні мережі та системи: Підручник 3-е видання, доп. та перероблене /– Львів: Вид.-во Нац. ун.-ту “Львівська політехніка”, 2015. – 540 с.

• written reports on laboratory course, oral questioning (30%);
• final control (control event – exam): written and oral form (70%).