SylabUZ
Course name | Circuit theory I |
Course ID | 06.2-WE-ELEKTP-CT01-Er |
Faculty | Faculty of Computer Science, Electrical Engineering and Automatics |
Field of study | Electrical Engineering |
Education profile | academic |
Level of studies | First-cycle Erasmus programme |
Beginning semester | winter term 2017/2018 |
Semester | 3 |
ECTS credits to win | 7 |
Course type | obligatory |
Teaching language | english |
Author of syllabus |
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The class form | Hours per semester (full-time) | Hours per week (full-time) | Hours per semester (part-time) | Hours per week (part-time) | Form of assignment |
Lecture | 30 | 2 | - | - | Exam |
Laboratory | 30 | 2 | - | - | Credit with grade |
Class | 30 | 2 | - | - | Credit with grade |
To familiarize students with basic laws and terms regarding electrical circuits
Mastering the basic methods of analysis of electrical circuits in a steady state
Introduction to methods of description and analysis of circuits with non-sinusoidal waveforms, three-phase circuits and four-terminals
Introduce basic skills in circuit analysis
Introduce basic skills in the use of basic devices for measuring current and voltage and circuit parameters
Introduce basic skills in the design of simple electrical circuits
Fundamentals of Electrical Engineering, Mathematical Analysis, Algebra, Physics
RLC resonance. Frequency characteristics, goodness of the circuit. Coils magnetically coupled.
Deformed signals. Non-sinusoidal, periodic, non-periodic and near-periodic signals. Fourier series. Linear time-invariant circuits with non-sinusoidal supply. Non-sinusoidal Power definitions. Parcevall's theorem.
Three-phase circuits. Star and triangular circuits. Three-phase sources and receivers. Multiphase symmetry. The symmetrical component method and its applications. Power in three-phase circuits.
Two-port elements. Equations for two-port elements. Two-port elements connections. Two-port element as a system for the transmission of signal and electricity. Differential and characteristic equations of Two-port elements.
Lecture: conventional lecture, problem lecture, discussion.
Exercises: calculating exercises, consultations.
Laboratory: laboratory exercises, working with the source document, working in groups.
Outcome description | Outcome symbols | Methods of verification | The class form |
Lecture: - exam - ability to solve tasks; Knowledge of laws, methods of description and analysis in the discussed scope.
Exercises: pass 3 colokwium or a final colokwium of the ability to solve tasks.
Laboratory: a condition of pass is to obtain positive grades from all laboratory exercises that are expected to be performed within the laboratory program.
Composition of the final grade: lecture: 40% + laboratory: 30% + exercises: 30%
Oppenheim A.V., Willsky A.S., Nawab H.: Signals & Systems, Prentice Hall, 1997.
Modified by dr hab. inż. Radosław Kłosiński, prof. UZ (last modification: 24-04-2017 15:26)