Graduate study programme

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Application of Electromagnetic Theory in Power Engineering DEc1-02

ECTS 7 | P 45 | A 0 | L 30 | K 0 | ISVU 149794 | Academic year: 2019./2020.

Course groups

Prikaži sve grupe na predmetu

Course lecturers

BARUKČIĆ MARINKO, Lecturer
HEDERIĆ ŽELJKO, Associate

Goals

Introduce students to basic electromagnetic field laws. Train students for medium complex analyses of electrical and magnetic fields. Train students for basic analyses of electromagnetic waves in space and on transmission lines. Introduce students to the basics of numerical methods in electromagnetic field calculations. Train students for numerical calculations of an electromagnetic field by using simulation software.

Conditions for enrollment

Requirements met for enrolling in the study programme

Course description

The field theory in the fundamentals of electrical engineering. Basic laws of electrical and magnetic fields. Maxwell equations. Boundary conditions. Poynting vector and theorem. Vector and scalar electromagnetic potentials. Electrostatic field. Imaging method. Stationary current fields. Biot-Savart law. Self and mutual inductance. Introduction to electromagnetic wave theory. Plane wave: basic features, reflection and refraction, energy density, power flow, polarisation. Plane wave in dispersion medium, attenuated wave on lines. EM wave propagation in free space and on transmission lines. Introduction to field numerical calculations. Basics of the finite element method.

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

Obligatory literature

1. 1 Mehmedović, M; Štefanko, S. Teorija polja i valova Osijek, ETF 2010.

2. 2 Ulaby Fawwaz; Michielssen Eric; Ravaioli Umberto Fundamentals of Applied Electromagnetics Prentice Hall, 2010.

3. 3 S. Berberović Teorijska elektrotehnika - odabrani primjeri Graphis, Zagreb, 1998.

4. 4 http://maxima.sourceforge.net/documentation.html


Pretraži literaturu na:

Recommended additional literature

1. 1 Z. Haznadar, Ž. Štih Elektromagnetizam 1 i 2 Školska knjiga, Zagreb, 1997.

2. 2 http://www.agros2d.org/down/

3. 3 Knapp Vladimir; Colić Petar Uvod u električna i magnetska svojstva materijala Zagreb Školska knjiga 1990

4. 4 http://www.femm.info/wiki/Documentation/

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. explain the basic physical laws and mathematical models of electrical and magnetic fields

2. choose the appropriate basic physical laws and mathematical models of electric and magnetic fields to solve middle complex problems in electrical and magnetic fields

3. use the physical laws of electromagnetic fields

4. validate the mathematical models of electromagnetic fields to solve middle complex problems

5. make a computer simulation model of middle complex problems in electrical and magnetic fields

6. validate the obtained results of simulated electromagnetic fields



Aktivnosti studenta: Vidi tablicu aktivnosti