Lectures:
1. Fundamentals of mathematics for description of physical field - vector calculus.
2. Physical units used in electrical engineering.
3. Physical principle of electromagnetic phenomena, distribution of electromagnetism in dependence on frequency.
4. Importance of Maxwell's equations in electrical engineering - connection with basic electrical engineering equations.
5. Use of electric field in industrial facilities.
6. Principles of electrical conductivity, dependence of conductivity on temperature, superconductivity.
7. Contact resistance, step potential, principles of earth resistance measurement.
8. Practical calculations of cable capacities and different types of lines.
9. Inductance and its determination in electrical equipment.
10. Energy conditions in electrical engineering.
11. Power manifestations of electromagnetism in electromagnets, electric motors and other electrical devices.
12. Eddy currents, surface and proximity phenomena, shielding of electromagnetic fields.
13. Electromagnetic interference due to wave radiation.
14. Effect of electromagnetic fields of different frequencies on human organism.
Computational exercises
1. Gauss theorem, Ampere's law, Biot-Savart's law.
2. Massive conductor resistance calculations.
3. Calculations of capacitances and inductances for simple geometric arrangement of conductors.
4. Energy calculations in power systems.
5. Calculations of forces in power systems.
Labs:
1. Methods of mapping of electromagnetic fields.
2. Force action of two conductors in different positions relative to each other
3. Effect of skin effect on impedance of conductive objects
4. Dependence of impedance of coil without core and with different types of cores on frequency
5. Frequency-dependent behavior of cables.
Projects performed by computers:
1. Visualization of the effects of electrostatics in a specific case
2. Solving the effects of the magnetic field busbar
1. Fundamentals of mathematics for description of physical field - vector calculus.
2. Physical units used in electrical engineering.
3. Physical principle of electromagnetic phenomena, distribution of electromagnetism in dependence on frequency.
4. Importance of Maxwell's equations in electrical engineering - connection with basic electrical engineering equations.
5. Use of electric field in industrial facilities.
6. Principles of electrical conductivity, dependence of conductivity on temperature, superconductivity.
7. Contact resistance, step potential, principles of earth resistance measurement.
8. Practical calculations of cable capacities and different types of lines.
9. Inductance and its determination in electrical equipment.
10. Energy conditions in electrical engineering.
11. Power manifestations of electromagnetism in electromagnets, electric motors and other electrical devices.
12. Eddy currents, surface and proximity phenomena, shielding of electromagnetic fields.
13. Electromagnetic interference due to wave radiation.
14. Effect of electromagnetic fields of different frequencies on human organism.
Computational exercises
1. Gauss theorem, Ampere's law, Biot-Savart's law.
2. Massive conductor resistance calculations.
3. Calculations of capacitances and inductances for simple geometric arrangement of conductors.
4. Energy calculations in power systems.
5. Calculations of forces in power systems.
Labs:
1. Methods of mapping of electromagnetic fields.
2. Force action of two conductors in different positions relative to each other
3. Effect of skin effect on impedance of conductive objects
4. Dependence of impedance of coil without core and with different types of cores on frequency
5. Frequency-dependent behavior of cables.
Projects performed by computers:
1. Visualization of the effects of electrostatics in a specific case
2. Solving the effects of the magnetic field busbar