the ability to apply information and communication technologies and programming skills for typical engineering tasks;
- the ability to apply professionally-profiled knowledge and practical skills to create new and maintain existing electrical, electrical and electromechanical systems and their components;
- the ability to apply analytical methods of analysis, mathematical modeling and conduct physical and mathematical experiments for engineering tasks solution and scientific research;
- the ability to analyze critically the main indicators of the system functioning and to evaluate the technical solutions and equipment in use;
- the ability to integrate knowledge from other disciplines, apply a systematic approach and take non-technical aspects into account in solving engineering problems and carrying out the research.

• further mathematics,
• physics;
• mathematical modeling in the electric power engineering;
• mathematical problems of electric power engineering;
• programming and software for engineering calculations.

Within the scope of the discipline the questions of dynamic systems macromodeling, principles, methods and algorithms of creation of continuous and discrete macromodels of complex dynamic electromechanical and electric power systems, development and use of software on their basis are considered. The discipline takes into account the peculiarities of training of masters of all specializations, which meet the requirements of the specialty "Electric Power Engineering, Electrical Engineering and Electromechanics".

Stakhiv P. D. Discrete macromodelling in electrical engineering and related fields. Monograph / P.G. Stakhiv, Yu. - L.: Lviv Polytechnic National University , 2014. - 260 p.
2. Matviychuk Ya. M. Mathematical Macromodelling of Dynamic Systems: Theory and Practice.-Lviv: Publishing House of Lviv, Ivan Franko National University, 2000. - 215 p.
3. Ljung L. Indexation of systems. Theory for the user / Ljung L. - M.: Science, 1991. - 432 с.
4. Kyrylenko O. V. Mathematical modeling in the electric power industry: textbook / O.V. Kirilenko, M.S. Seheda, O.F. Butkevych, T.A. Mazur. - Lviv: National University "Lviv Polytechnic", 2010. - 608

Current control - Preparing, execution and discussion of laboratory tasks (40 %)
Final control is carried out during the session in writing and in oral form (60 %)

the ability to apply information and communication technologies and programming skills for typical engineering tasks;
- the ability to apply professionally-profiled knowledge and practical skills to create new and maintain existing electrical, electrical and electromechanical systems and their components;
- the ability to apply analytical methods of analysis, mathematical modeling and conduct physical and mathematical experiments for engineering tasks solution and scientific research;
- the ability to analyze critically the main indicators of the system functioning and to evaluate the technical solutions and equipment in use;
- the ability to integrate knowledge from other disciplines, apply a systematic approach and take non-technical aspects into account in solving engineering problems and carrying out the research.

• further mathematics,
• physics;
• mathematical modeling in the electric power engineering;
• mathematical problems of electric power engineering;
• programming and software for engineering calculations.

Within the scope of the discipline the questions of dynamic systems macromodeling, principles, methods and algorithms of creation of continuous and discrete macromodels of complex dynamic electromechanical and electric power systems, development and use of software on their basis are considered. The discipline takes into account the peculiarities of training of masters of all specializations, which meet the requirements of the specialty "Electric Power Engineering, Electrical Engineering and Electromechanics".

1. Stakhiv P. D. Discrete macromodelling in electrical engineering and related fields. Monograph / P.G. Stakhiv, Yu. - L.: Lviv Polytechnic National University , 2014. - 260 p.
2. Matviychuk Ya. M. Mathematical Macromodelling of Dynamic Systems: Theory and Practice.-Lviv: Publishing House of Lviv, Ivan Franko National University, 2000. - 215 p.
3. Ljung L. Indexation of systems. Theory for the user / Ljung L. - M.: Science, 1991. - 432 с.
4. Kyrylenko O. V. Mathematical modeling in the electric power industry: textbook / O.V. Kirilenko, M.S. Seheda, O.F. Butkevych, T.A. Mazur. - Lviv: National University "Lviv Polytechnic", 2010. - 608

Current control - Preparing, execution and discussion of laboratory tasks (40 %)
Final control is carried out during the session in writing and in oral form (60 %)

the ability to apply information and communication technologies and programming skills for typical engineering tasks;
- the ability to apply professionally-profiled knowledge and practical skills to create new and maintain existing electrical, electrical and electromechanical systems and their components;
- the ability to apply analytical methods of analysis, mathematical modeling and conduct physical and mathematical experiments for engineering tasks solution and scientific research;
- the ability to analyze critically the main indicators of the system functioning and to evaluate the technical solutions and equipment in use;
- the ability to integrate knowledge from other disciplines, apply a systematic approach and take non-technical aspects into account in solving engineering problems and carrying out the research.

• further mathematics,
• physics;
• mathematical modeling in the electric power engineering;
• mathematical problems of electric power engineering;
• programming and software for engineering calculations.

Within the scope of the discipline the questions of dynamic systems macromodeling, principles, methods and algorithms of creation of continuous and discrete macromodels of complex dynamic electromechanical and electric power systems, development and use of software on their basis are considered. The discipline takes into account the peculiarities of training of masters of all specializations, which meet the requirements of the specialty "Electric Power Engineering, Electrical Engineering and Electromechanics".

1. Stakhiv P. D. Discrete macromodelling in electrical engineering and related fields. Monograph / P.G. Stakhiv, Yu. - L.: Lviv Polytechnic National University , 2014. - 260 p.
2. Matviychuk Ya. M. Mathematical Macromodelling of Dynamic Systems: Theory and Practice.-Lviv: Publishing House of Lviv, Ivan Franko National University, 2000. - 215 p.
3. Ljung L. Indexation of systems. Theory for the user / Ljung L. - M.: Science, 1991. - 432 с.
4. Kyrylenko O. V. Mathematical modeling in the electric power industry: textbook / O.V. Kirilenko, M.S. Seheda, O.F. Butkevych, T.A. Mazur. - Lviv: National University "Lviv Polytechnic", 2010. - 608

Current control - Preparing, execution and discussion of laboratory tasks (40 %)
Final control is carried out during the session in writing and in oral form (60 %)

the ability to apply information and communication technologies and programming skills for typical engineering tasks;
- the ability to apply professionally-profiled knowledge and practical skills to create new and maintain existing electrical, electrical and electromechanical systems and their components;
- the ability to apply analytical methods of analysis, mathematical modeling and conduct physical and mathematical experiments for engineering tasks solution and scientific research;
- the ability to analyze critically the main indicators of the system functioning and to evaluate the technical solutions and equipment in use;
- the ability to integrate knowledge from other disciplines, apply a systematic approach and take non-technical aspects into account in solving engineering problems and carrying out the research.

• further mathematics,
• physics;
• mathematical modeling in the electric power engineering;
• mathematical problems of electric power engineering;
• programming and software for engineering calculations.

Within the scope of the discipline the questions of dynamic systems macromodeling, principles, methods and algorithms of creation of continuous and discrete macromodels of complex dynamic electromechanical and electric power systems, development and use of software on their basis are considered. The discipline takes into account the peculiarities of training of masters of all specializations, which meet the requirements of the specialty "Electric Power Engineering, Electrical Engineering and Electromechanics".

1. Stakhiv P. D. Discrete macromodelling in electrical engineering and related fields. Monograph / P.G. Stakhiv, Yu. - L.: Lviv Polytechnic National University , 2014. - 260 p.
2. Matviychuk Ya. M. Mathematical Macromodelling of Dynamic Systems: Theory and Practice.-Lviv: Publishing House of Lviv, Ivan Franko National University, 2000. - 215 p.
3. Ljung L. Indexation of systems. Theory for the user / Ljung L. - M.: Science, 1991. - 432 с.
4. Kyrylenko O. V. Mathematical modeling in the electric power industry: textbook / O.V. Kirilenko, M.S. Seheda, O.F. Butkevych, T.A. Mazur. - Lviv: National University "Lviv Polytechnic", 2010. - 608

Semester control - Preparing, execution and discussion of laboratory tasks (40 %)
Final control is carried out during the session in writing and in oral form (60 %)

the ability to apply information and communication technologies and programming skills for typical engineering tasks;
- the ability to apply professionally-profiled knowledge and practical skills to create new and maintain existing electrical, electrical and electromechanical systems and their components;
- the ability to apply analytical methods of analysis, mathematical modeling and conduct physical and mathematical experiments for engineering tasks solution and scientific research;
- the ability to analyze critically the main indicators of the system functioning and to evaluate the technical solutions and equipment in use;
- the ability to integrate knowledge from other disciplines, apply a systematic approach and take non-technical aspects into account in solving engineering problems and carrying out the research.

• further mathematics,
• physics;
• mathematical modeling in the electric power engineering;
• mathematical problems of electric power engineering;
• programming and software for engineering calculations.

Within the scope of the discipline the questions of dynamic systems macromodeling, principles, methods and algorithms of creation of continuous and discrete macromodels of complex dynamic electromechanical and electric power systems, development and use of software on their basis are considered. The discipline takes into account the peculiarities of training of masters of all specializations, which meet the requirements of the specialty "Electric Power Engineering, Electrical Engineering and Electromechanics".

1. Stakhiv P. D. Discrete macromodelling in electrical engineering and related fields. Monograph / P.G. Stakhiv, Yu. - L.: Lviv Polytechnic National University , 2014. - 260 p.
2. Matviychuk Ya. M. Mathematical Macromodelling of Dynamic Systems: Theory and Practice.-Lviv: Publishing House of Lviv, Ivan Franko National University, 2000. - 215 p.
3. Ljung L. Indexation of systems. Theory for the user / Ljung L. - M.: Science, 1991. - 432 с.
4. Kyrylenko O. V. Mathematical modeling in the electric power industry: textbook / O.V. Kirilenko, M.S. Seheda, O.F. Butkevych, T.A. Mazur. - Lviv: National University "Lviv Polytechnic", 2010. - 608 p.

Semester control - Preparing, execution and discussion of laboratory tasks (40 %)
Final control is carried out during the session in writing and in oral form (60 %)

the ability to apply information and communication technologies and programming skills for typical engineering tasks;
- the ability to apply professionally-profiled knowledge and practical skills to create new and maintain existing electrical, electrical and electromechanical systems and their components;
- the ability to apply analytical methods of analysis, mathematical modeling and conduct physical and mathematical experiments for engineering tasks solution and scientific research;
- the ability to analyze critically the main indicators of the system functioning and to evaluate the technical solutions and equipment in use;
- the ability to integrate knowledge from other disciplines, apply a systematic approach and take non-technical aspects into account in solving engineering problems and carrying out the research.

• further mathematics,
• physics;
• mathematical modeling in the electric power engineering;
• mathematical problems of electric power engineering;
• programming and software for engineering calculations.

Within the scope of the discipline the questions of dynamic systems macromodeling, principles, methods and algorithms of creation of continuous and discrete macromodels of complex dynamic electromechanical and electric power systems, development and use of software on their basis are considered. The discipline takes into account the peculiarities of training of masters of all specializations, which meet the requirements of the specialty "Electric Power Engineering, Electrical Engineering and Electromechanics".

1. Stakhiv P. D. Discrete macromodelling in electrical engineering and related fields. Monograph / P.G. Stakhiv, Yu. - L.: Lviv Polytechnic National University , 2014. - 260 p.
2. Matviychuk Ya. M. Mathematical Macromodelling of Dynamic Systems: Theory and Practice.-Lviv: Publishing House of Lviv, Ivan Franko National University, 2000. - 215 p.
3. Ljung L. Indexation of systems. Theory for the user / Ljung L. - M.: Science, 1991. - 432 с.
4. Kyrylenko O. V. Mathematical modeling in the electric power industry: textbook / O.V. Kirilenko, M.S. Seheda, O.F. Butkevych, T.A. Mazur. - Lviv: National University "Lviv Polytechnic", 2010. - 608

Semester control - Preparing, execution and discussion of laboratory tasks (40 %)
Final control is carried out during the session in writing and in oral form (60 %)