Gurantor department | Department of Electrical Engineering | Credits | 8 |

Subject guarantor | doc. Ing. Lubomír Ivánek, CSc. | Subject version guarantor | doc. Ing. Lubomír Ivánek, CSc. |

Study level | undergraduate or graduate | Requirement | Compulsory |

Year | 1 | Semester | winter |

Study language | English | ||

Year of introduction | 2015/2016 | Year of cancellation | |

Intended for the faculties | FEI, USP | Intended for study types | Bachelor |

Instruction secured by | |||
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Login | Name | Tuitor | Teacher giving lectures |

H1R15 | Ing. Karel Chrobáček, Ph.D. | ||

DUD57 | Ing. Jan Dudek, Ph.D. | ||

IVA10 | doc. Ing. Lubomír Ivánek, CSc. | ||

ORS60 | Ing. Petr Orság, Ph.D. | ||

OTY0002 | Ing. Jan Otýpka | ||

ZAJ02 | Ing. Stanislav Zajaczek, Ph.D. |

Extent of instruction for forms of study | ||
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Form of study | Way of compl. | Extent |

Full-time | Credit and Examination | 2+4 |

Combined | Credit and Examination | 8+6 |

The aim of education is give creative lessons in physical laws and principles to analysis of three-phase circuit, transient phenomena, two-port network, frequency response and distributed lines. After education student is able to calculated current, voltage, power and energy in circuit anyplace and then on the basis of them look on properties of electrical device. Student practices obtained knowledge and acquirements energetically.

Lectures

Individual consultations

Tutorials

Experimental work in labs

Project work

The course "Circuit theory I" deals with the analysis of the electrical circuits - the most typical structure in the electrical engineering. Electrical circuits knowledge are basic knowledge and they are a prerequisite for advanced circuit courses (electronic, measuring and control systems, electrical machines, etc.). The basic aim is to determine voltages and currents in the electrical circuit, and then identify (from these knowledge) the properties of the circuit or system. Theses: elementary models of electromagnetic effects, circuit analysis algorithms, transients in the linear circuits (the 1. order), experimental measurements (Associate professor Josef Punčochář).

Mikulec, M.: Basic Circuit Theory I.,ČVUT 1995
Mikulec, M., Havlíček, V.: Basic Circuit Theory II.ČVUT 1996
Havlíček, V.-Čmejla, R.: Basic Circuit Theory I. (Exercises ), ČVUT 1996
Huelsman, P.L.: Basic Circuit Theory. Prentice-Hall International, 1991, ISBN 0-13-063157-4

Mikulec, M.: Basic Circuit Theory I.,ČVUT 1995
Mikulec, M., Havlíček, V.: Basic Circuit Theory II.ČVUT 1996
Havlíček, V.-Čmejla, R.: Basic Circuit Theory I. (Exercises ), ČVUT 1996
Huelsman, P.L.: Basic Circuit Theory. Prentice-Hall International, 1991, ISBN 0-13-063157-4

Condition for conferment of credit:
Student must to obtain 3 points until the end of 14-th semester week. Student is in a position to obtain 0 to 33 points (individual work) and 0 to 9 points (semestral project).

Additional requirements for students are not.

Subject has no prerequisities.

Subject has no co-requisities.

Lectures:
Introduction to the subject. Definition of basic concepts.
• Thevenin`s and Norton`s theorem. Superposition principle.
• Circuit analysis in harmonic steady state.
• Circuit topology. Kirchhoff`s laws. Analysis of composit electrical circuits.
• Circuit analysis by means of section voltage method and loop current method. Reciprocity and compensation principles.
• Resonance, quality factor, frequecy bandwidth. Immittance functions.
• Inductive coupling, mutual induktance. Elementry models of transformer.
• Analysis of circuit with non-linear elements. Determination of linearized differential and difference parameters.
• Magnetic circuits
• Aproximation of non-harmonic waves by means of Fourier`s series and time series of unit steps.
• Analysis of circuit with non-harmonic waves, power, power factor.
• Determination of circuit parameters and immittances of technical elements. Equivalence and duality principles.
• Dielectrical circuits.
• consultation
Seminars:
• Determination of resistances and source parameters.Current and voltage deviders.
• Step by step method. Transfiguration of the D-to-Y circuit.
• Superposition principle.
• Phasor diagrams, power, immittances.
• Section voltages method.
• Loop currents method.
• Determination of resonace frequency, compensation of quantity and power reactive components.
• Formation of circuit equations in inductive coupling circuit.
• Analysis of circuit with non-linear elements.
• Superposition of elementary analog functions.
• Superposition of unit steps.
• Analysis of circuit with non-harmonic waves.
• Calculation of powers and immittances in circuit with non-harmonic waves.
• Analysis of dielectrical circuits.
Laboratory works:
• Knowledge test.
• Calculation of quantity root-mean-squar values, powers, and woks by means of scalar product of current and voltage.
• Measurement of source parameters.
• Verification of Thevenin`s and Norton`s theorems.
• Verification of computational method, compensation and reciprocitz principles.
• Measurement of devices with non-linear characteristics
• Measurement of quantities in series connection of coil and condensator.
• Measurement of quantities in circuits with series end paralel resonance. Calculation of quality factor.
• Determination of inductive coupling parameters.
• Modelling of quantities by means of goniometrical functions.
• Modelling of quantities by means of unit steps.
• Measurement of non-harmonic quantities in elementary circuits.
• Determination of circuit parameters by means of measured instantaneous values current and voltage.
• Conferment of credit.
Semester projekt:
• 1st Circuit analysis by means of section voltage method and loop current method.
Proofs:
1st Knowledge test.
2nd Circut analysis by means of superposition principle.
3th Analysis of elementary circuit in harmonic steady state.

Conditions for completion are defined only for particular subject version and form of study

Academic year | Programme | Field of study | Spec. | Form | Study language | Tut. centre | Year | W | S | Type of duty | |
---|---|---|---|---|---|---|---|---|---|---|---|

2019/2020 | (B2649) Electrical Engineering | P | English | Ostrava | 1 | Compulsory | study plan | ||||

2019/2020 | (B2649) Electrical Engineering | K | English | Ostrava | 1 | Compulsory | study plan | ||||

2018/2019 | (B3973) Automotive Electronic Systems | P | English | Ostrava | 1 | Compulsory | study plan | ||||

2018/2019 | (B2649) Electrical Engineering | P | English | Ostrava | 1 | Compulsory | study plan | ||||

2018/2019 | (B2649) Electrical Engineering | K | English | Ostrava | 1 | Compulsory | study plan | ||||

2017/2018 | (B2649) Electrical Engineering | P | English | Ostrava | 1 | Compulsory | study plan | ||||

2017/2018 | (B2649) Electrical Engineering | K | English | Ostrava | 1 | Compulsory | study plan | ||||

2017/2018 | (B3973) Automotive Electronic Systems | P | English | Ostrava | 1 | Compulsory | study plan | ||||

2016/2017 | (B2649) Electrical Engineering | P | English | Ostrava | 1 | Compulsory | study plan | ||||

2016/2017 | (B2649) Electrical Engineering | K | English | Ostrava | 1 | Compulsory | study plan | ||||

2015/2016 | (B2649) Electrical Engineering | P | English | Ostrava | 1 | Compulsory | study plan | ||||

2015/2016 | (B2649) Electrical Engineering | K | English | Ostrava | 1 | Compulsory | study plan |

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