Principles of Electrical Engineering
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Course informations
| Study program level |
Undergraduate |
| Study program |
Electrical Engineering |
| Study program direction |
Telecommunications and informatics |
| Course year |
1. |
| Course semester |
I |
| Course status |
Core |
| ECTS |
6 |
| Lectures (h) |
30 |
| Excercises (h) |
30 |
| Seminars (h) |
- |
Course objectives
Acquiring knowledge and skills required for independent work and successful continuation of education. To clarify the basic tenants of the course and to encourage the application of certain units on the relevant areas.
Knowledge of basic electromagnetic laws, size and units describing electric and magnetic field; calculations in a simple circuit, calculations of electric field, magnetic field, capacitance, inductance and resistance for simple structures; measurement by ammeter, voltmeter, vat, smear, teslameter and oscilloscope
Course outcomes
- To name the basic physical sizes in an electric and magnetic field (charge, electric field, magnetic field, potential, voltage) and electric circuit (current, voltage, power, electrical resistance, inductance, capacitance, inter-inductance)
- To use basic laws, mathematical phrases and mathematical models to solve simpler problems in electric and magnetic fields, magnetic circuits and actual electrical circuits of DC current with resistors and capacitors in a steady state.
- To apply Kirchhoff’s laws to solve electric circuits of DC current with linear elements in a steady state.
- To apply basic laws for electric and magnetic fields to solve simple problems in electric and magnetic fields and simple magnetic circles.
- To calculate examples of DC electric networks.
- To analyze a given problem, calculate the required sizes and estimate the physical meaning of the calculated values. To connect the simple electric circuits of DC current.
- To measure the basic electrical sizes in electrical circuits of the DC current.
Course content
Electrostatics: basic terms of electricity, Coulomb's law, electric field, Gauss law, electric potential, electric dipole, electrostatic field conductor, electrostatic dielectrics, electrical capacity. Current circuit: charge motion, electric resistance, complex current circuits, basic electrical measurements
Electromagnetism: magnetic field, magnetic field forces, magnetic field work, magnetic properties magnetic, magnetic circuit, electromagnetic induction, energy and force in the magnetic field.
