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Fundamentals of Electrical Engineering I SAE101

ECTS 7 | P 45 | A 30 | L 15 | K 0 | ISVU 74055 | Academic year: 2019./2020.

Course groups

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Course lecturers

BENŠIĆ TIN, Associate
FILIĆ MIRKO, Associate

Course description

Structure of matter. Conductors and insulators. Coulomb's law. Electric field. Gauss's law. Electric potential and voltage. Electric circuit and electric current. Electric resistance. Ohm's law. Kirchhoff's laws. Power and energy in a current circuit, Joule's law. Methods and theorems for solving electric networks. Material in the electric field. Electric flux vector. Capacitance and capacitors. Energy of the electrostatic field. Electrostatic networks. Magnetic field, flux density and magnetic field intensity. Magnetic force on a current-carrying conductor. Biot-Savart's law. Ampere's law. Electromagnetic induction. Material in the magnetic field. Magnetic circuits. Self- and mutual inductance. Energy of the magnetic field. Laboratory practice: Work in the laboratory. Ohm's law. Kirchhoff's laws. Complex direct current networks. Electrostatic networks. Magnetic field and coil inductance. Faraday's law.

Knowledge and skills acquired

Fundamental knowledge of electromagnetic phenomena required for following the study of professional courses in electrical engineering.

Teaching methods

Lectures (3 hours per week), problem solving (2 hours per week), laboratory practice (1 hour per week) Lecturing by means of PowerPoint presentations, problem solving and laboratory practice with active participation of students by continuous assessment of the acquired knowledge.

Student requirements

Defined by the Student evaluation criteria of the Faculty of Electrical Engineering, Computer Science and Information Technology Osijek and paragraph 1.9

Monitoring of students

Defined by the Student evaluation criteria of the Faculty of Electrical Engineering, Computer Science and Information Technology Osijek and paragraph 1.9

Student assessment

Two revision exams during the semester and an oral exam for students who meet the requirements defined by the Student evalution criteria (points earned in revision exams and grade awarded in design exercises). Other students must take the written and oral exam.

Obligatory literature

1. 1 Kuzmanović, B. Osnove elektrotehnike I Element, 2000., Zagreb, ISBN 953-197-128-5

2. 2 Prasad, Rajendra Fundamentals of Electronic Engineering Cengage Learning. 2012., ISBN 9781408072615

3. 3 V. Pinter Osnove elektrotehnike I i II Tehnička knjiga, Zagreb, 1989.

4. 4 Šehović, Felja, Tkalić Osnove elektrotehnike, zbirka primjera prvi dio Školska knjiga, Zagreb 1980.

Pretraži literaturu na:

Recommended additional literature

1. 1 Felja, Koračin Zbirka zadataka i riješenih primjera iz osnova elektrotehnike, 1. dio Školska knjiga, Zagreb, 1985.

2. 2 M. Pužar, I. Mandić, M. Božić Osnove elektrotehnike I, nastavni materijal na moodleu Elektrotehnički fakutet Osijek, 2006.

Examination methods

Students' evaluation during the course and oral examination for students that satisfy by scoring, written and oral examination for other students.

Course assessment

Conducting university questionnaires on teachers (student-teacher relationship, transparency of assessment criteria, motivation for teaching, teaching clarity, etc.). Conducting Faculty surveys on courses (upon passing the exam, student self-assessment of the adopted learning outcomes and student workload in relation to the number of ECTS credits allocated to activities and courses as a whole).

Overview of course assesment

Learning outcomes
Upon successful completion of the course, students will be able to:

1. define basic physical quantities in the electric and magnetic field (charge, electric field, magnetic field, potential, voltage) and electrical circuit (current, voltage, power, electrical resistance, inductance, capacitance, mutual inductance)

2. combine basic laws, mathematical expressions and models to solve simpler problems in electrical and magnetic fields, magnetic circuits and real current circuits with DC resistors and capacitors

3. analyse and solve complex DC electric circuits with linear resistances and capacities in steady state and magnetic circuits with and without a ferromagnetic core

4. select an optimal method and theorem for solving DC circuits with linear elements in a steady state

5. interpret problem tasks solved in electrical and magnetic fields and simple magnetic circuits

6. compare analytical and numerical mathematical models of DC electric circuits with linear elements in the steady state using Kirchhoff's laws and magnetic circuits with and without a ferromagnetic core

7. test simple DC electrical circuits with real resistors, coils and capacitors

8. organise basic electrical measurements in DC electric circuits

Aktivnosti studenta: Vidi tablicu aktivnosti