University of West Bohemia in Pilsen
Study programmes & Course catalogue
for academic year 2025/2026
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Course: Theory of Electrical Engineering 2

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Course title Theory of Electrical Engineering 2
Course code KEP/TEL2
Organizational form of instruction Lecture + Tutorial
Level of course Bachelor
Year of study not specified
Semester Summer
Number of ECTS credits 4
Language of instruction Czech, English
Status of course Compulsory
Form of instruction Face-to-face
Work placements This is not an internship
Recommended optional programme components None
Lecturer(s)
  • Tělecká Jana, prof. Ing. CSc.
  • Kraupnerová Yuliia, Ing. Ph.D.
  • Žerebák Emil, doc. Ing. Ph.D.
  • Levý Petr, Ing.
  • Zvára David, Ing.
  • Jhala František, Ing. Ph.D.
  • Prokeš Vojtěch, doc. Ing. CSc.
  • Pavlovský Igor, Ing. Ph.D.
  • Šmídová Šárka, Ing. Ph.D.
  • Trubka Josef, Ing.
Course content
1. Asymmetrical Three-Phase System - Power in a three-phase system. 2. Mutual Inductance - Circuits with non-harmonic voltage and current waveforms. Decomposition of periodic functions into a Fourier series. 3. Analysis of Circuits with Non-Harmonic Sources - Effective values of non-harmonic waveforms. Power in circuits with non-harmonic sources. 4. Two-Port Networks - Determination of characteristic matrices of two-port networks. 5. Equivalent Two-Port Networks - Connecting two-port networks. Circuit functions of two-port networks. Transmission properties - frequency characteristics. 6. Wave Impedance - Impedance matching. Basic types of filters. 7. Frequency Characteristics of Filters - Energy relationships in passive elements L, C, and R. 8. Physical Nature of Transient Processes - Initial conditions. Solution of transient processes in first-order circuits with DC sources (R-L and R-C). 9. Solution of Transient Processes in First-Order Circuits - Circuits with multiple loops and time-varying sources. 10. Solution of Transient Processes in Second-Order Circuits - Physical analysis. 11. Solution of Transient Processes in Higher-Order Circuits - State variable method. 12. Laplace Transform Method for Solving Transient Processes 13. Laplace Transform Method for Solving Transient Processes (continued)

Learning activities and teaching methods
  • Preparation for formative assessments (2-20) - 6 hours per semester
  • Contact hours - 52 hours per semester
  • Preparation for an examination (30-60) - 30 hours per semester
  • Preparation for laboratory testing; outcome analysis (1-8) - 6 hours per semester
  • Undergraduate study programme term essay (20-40) - 14 hours per semester
  • Contact hours - 16 hours per semester
  • unspecified - 36 hours per semester
prerequisite
Knowledge
to describe a linear electrical circuit by a set of equations
to explain methods for DC analysis
to explain methods for circuit analysis in a harmonic steady state
Skills
to solve a system of linear algebraic equations
to use the integral and differential calculus of one variable
to solve algebraic equations
Competences
N/A
N/A
N/A
N/A
learning outcomes
Knowledge
to formulate equations describing nonlinear circuits
to explain the physical nature of transient phenomena
to distinguish the type of linear electrical filter according to the scheme, frequency characteristics, transmission and impulse functions
Skills
to perform a computer simulation of solutions of transient phenomena of higher order
to solve transients in first order circuits
to calculate initial conditions and new steady-states for higher order circuits
to find a transfer function and draw a frequency characteristic of given linear two-port network
to compose equations for transient phenomena
Competences
N/A
N/A
teaching methods
Knowledge
Lecture supplemented with a discussion
Practicum
Self-study of literature
Skills
Practicum
Laboratory work
Competences
Lecture supplemented with a discussion
Practicum
Laboratory work
assessment methods
Knowledge
Combined exam
Test
Seminar work
Individual presentation at a seminar
Skills
Combined exam
Seminar work
Individual presentation at a seminar
Test
Competences
Test
Combined exam
Recommended literature
  • Benešová, Zdeňka; Ledvinová, Marcela. Základy elektrických obvodů v příkladech. ZČU, Plzeň, 2015. ISBN 978-80-261-0432-2.
  • Charles Alexander, Sadiku Matthew. Fundamentals of Electric Circuits. McGraw-Hill, 2012. ISBN 978-0073380575.
  • Mayer, Daniel. Úvod do teorie elektrických obvodů. Praha : SNTL, 1981.


Study plans that include the course
Faculty Study plan (Version) Category of Branch/Specialization Recommended year of study Recommended semester
University of West Bohemia in Pilsen, date of update: 12.11.2025 23:51. Data created for academic year 2025/2026