ON-1. To reveal the content of the research work. To substantiate, analyze and formulate options for decisions. Apply the methods of scientific research and system analysis in the development of automation and control systems;

ON-2. To analyze methods of modeling transformers, electric motors, electric drives and automatic control systems using modern computer applications, mathematical description of objects and its use in the modeling process, statistical methods of processing modeling results and the modeling process from the description of the object to the creation of a mathematical model and experiment;

ON-3 To show in-depth professional knowledge in the field of mathematical modeling of elements of wind turbines. Demonstrate ideas about the possibilities of mathematical modeling, classification of mathematical models and the scope of their applicability. They will receive answers to what fundamental qualitative questions a mathematical model can answer. To develop practical skills of decomposition, abstraction in solving problems in wind energy;

ON-4 To master the methodology of bringing the data of short-term expeditionary measurements to the data of the reference station. Gain experience in organizing and conducting wind observations at the site of the proposed installation of a wind turbine. To master the method of calculating hydropower resources and the measuring system for monitoring water flow;

ON-5 To master the prerequisites for energy efficiency on a global scale and the prerequisites for energy efficiency and energy saving, the methodology of inspection of electric networks, technical solutions for energy efficiency, problems of quality of electric energy in distribution electric networks and consumers of electricity, basic requirements for reliability of power supply and methods of its improvement, issues of regulation of power consumption modes, the legislative base of Kazakhstan;

ON-6 To study the main types of power electronics elements and the principles of construction of converter devices, such as AC-to-DC converters, DC-to-AC converters, frequency converters, etc.;

ON-7 Master the principles of construction, operation of compensated and controlled (flexible) EHV power transmission lines and their influence on the distribution of voltage and reactive power, and the equations of a long line, and its wave characteristics.

ON-8 To master the theory of transmission of electrical energy at ultra-high voltage (EHV) over long distances. Types and classification of modern EHV power lines. Parameters and design features of supports, wires and overvoltage protection. The concept of bandwidth. Criteria for assessing the capacity and the impact on it of the design of modern EHV lines. Basic design parameters and fundamentals of mechanical calculation.

ON-9 To study the properties and characteristics of static compensating devices, methods for their calculation and selection of parameters. Static thyristor compensators. Schemes and principle of operation of asynchronous compensators. Uncontrolled longitudinal compensation devices. Controlled longitudinal compensation devices. Complex regulation of active and reactive power of a transmission line using a "combined regulator".

ON-10 Demonstrate in-depth knowledge of modern industrial production characterized by an increase in the scale and complication of technological processes, an increase in the unit capacity of individual units and installations, the use of intensive, high-speed modes, increased requirements for product quality, personnel safety, equipment safety and the environment. Economical, reliable and safe operation of complex industrial facilities can only be ensured with the help of perfect principles and technical means.

ON-11 Analyze the features of centrifugal load and options for creating object-oriented electric drive systems that minimize energy losses and methods for calculating parameters, static and dynamic characteristics, choosing elements of an automated electric drive for various purposes