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Course info
KEP / TEL3
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Course description
Department/Unit / Abbreviation
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KEP
/
TEL3
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Academic Year
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2024/2025
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Academic Year
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2024/2025
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Title
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Theory of Electrical Engineering 3
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Form of course completion
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Exam
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Form of course completion
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Exam
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Accredited / Credits
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Yes,
5
Cred.
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Type of completion
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Combined
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Type of completion
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Combined
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Time requirements
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Lecture
2
[Hours/Week]
Tutorial
3
[Hours/Week]
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Course credit prior to examination
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Yes
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Course credit prior to examination
|
Yes
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Automatic acceptance of credit before examination
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No
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Included in study average
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YES
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Language of instruction
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Czech, English
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Occ/max
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|
|
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Automatic acceptance of credit before examination
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No
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Summer semester
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0 / -
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0 / -
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0 / -
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Included in study average
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YES
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Winter semester
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150 / -
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0 / -
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0 / -
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Repeated registration
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NO
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Repeated registration
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NO
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Timetable
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Yes
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Semester taught
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Winter semester
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Semester taught
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Winter semester
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Minimum (B + C) students
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10
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Optional course |
Yes
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Optional course
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Yes
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Language of instruction
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Czech, English
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Internship duration
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0
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No. of hours of on-premise lessons |
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Evaluation scale |
1|2|3|4 |
Periodicity |
každý rok
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Evaluation scale for credit before examination |
S|N |
Periodicita upřesnění |
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Fundamental theoretical course |
Yes
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Fundamental course |
No
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Fundamental theoretical course |
Yes
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Evaluation scale |
1|2|3|4 |
Evaluation scale for credit before examination |
S|N |
Substituted course
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None
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Preclusive courses
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N/A
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Prerequisite courses
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N/A
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Informally recommended courses
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N/A
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Courses depending on this Course
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KEP/SBTE
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Histogram of students' grades over the years:
Graphic PNG
,
XLS
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Course objectives:
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To familiarize students with basic properties and laws of a stationary electromagnetic field, electrostatic field and current field. To explain Ampere's law. To define the relationships and procedures for calculating capacitance and inductance, calculating resistance, capacitance, and inductance for simple configurations. To understand the analogy of electrical and magnetic circuits and methods for solving them. To define forces and energies in electric and magnetic fields. To define and explain the differences in the non-stationary magnetic field. Explain Faraday's induction law and surface phenomenon.
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Requirements on student
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Credits:
- writing control tests and obtaining required number of points
- elaboration of assigned homework
- participation in laboratory exercises and submission of results in the required form within a week after practicing
- active participation in exercises
Examination:
Knowledge of all materials from lectures and seminars.
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Content
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1. Introduction, basic variables, sorting of the fields. Maxwell's equations for stationary fields. Electrostatic field, Electrostatic induction and polarization.
2. Coulomb law, scalar potential, the definition of capacity. Analysis of simple electrostatic fields, calculation of charge distribution and capacity.
3. Energy and forces in an electric field.
4. Electric current field. Joule's losses, electrical resistance. Analysis of simple Electrical current fields.
5. Stationary magnetic field, basic properties, and quantities, analysis of simple magnetic fields.
6. Superposition, calculation of magnetic flux, and static definition of inductance.
7. Electrical field analogy in the dielectric and conductive environment and magnetic field. Vector magnetic potential.
8. Equations for stationary electromagnetic field potentials. Analytical solution of simple boundary problems in planar, axial, and spherical symmetry.
9. Energy of stationary magnetic field. Forces in a stationary magnetic field.
10. Magnetic circuits, the analysis methods.
11. Energy definition of inductance, calculation of coil inductances.
12. Non-stationary electromagnetic field, Faraday's induction law, induced voltage.
13. Surface phenomena - Physical interpretation, skin depth.
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Activities
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Fields of study
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Studentům jsou k dispozici prezentace v el. podobě. Tyto obsahují všechny základní informace a doplňující ukázky a příklady.
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Guarantors and lecturers
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-
Guarantors:
Doc. Ing. Václav Kotlan, Ph.D. ,
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Lecturer:
Prof. Ing. Zdeňka Benešová, CSc. (100%),
Doc. Ing. Václav Kotlan, Ph.D. (100%),
Ing. Marcela Ledvinová, Ph.D. (100%),
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Tutorial lecturer:
Ing. Roman Hamar, Ph.D. (25%),
Doc. Ing. Václav Kotlan, Ph.D. (100%),
Ing. Marcela Ledvinová, Ph.D. (100%),
Ing. Iveta Petrášová, Ph.D. (100%),
Ing. Iveta Petrášová (25%),
Ing. Karel Pospíšil (25%),
Ing. Petr Stašek (100%),
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Literature
|
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Time requirements
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All forms of study
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Activities
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Time requirements for activity [h]
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Preparation for laboratory testing; outcome analysis (1-8)
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8
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Preparation for formative assessments (2-20)
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5
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Undergraduate study programme term essay (20-40)
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20
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Preparation for an examination (30-60)
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40
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Total
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73
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Combined form of study
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Activities
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Time requirements for activity [h]
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E-learning [dáno e-learningovým kurzem]
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45
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Contact hours
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20
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Total
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65
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Full-time form of study
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Activities
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Time requirements for activity [h]
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Contact hours
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65
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Total
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65
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Prerequisites
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Knowledge - students are expected to possess the following knowledge before the course commences to finish it successfully: |
to handle systems of differential equations, nonlinear algebraic equations, integral calculus, functions of multiple variables, differential and integral calculus of multiple variables, vector analysis |
Skills - students are expected to possess the following skills before the course commences to finish it successfully: |
to quantify numerical results |
to solve the sets of differential equations |
to solve the functions of multiple variables |
to solve the nonlinear algebraic equations |
to use the vector analysis |
Competences - students are expected to possess the following competences before the course commences to finish it successfully: |
N/A |
N/A |
N/A |
N/A |
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Learning outcomes
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Knowledge - knowledge resulting from the course: |
to explain the theory of stationary magnetic fields, electrostatic and current fields |
to characterize the properties and to give the basic quantities and regularities of the stationary magnetic field, electrostatic and current field |
to characterize the differences in the non-stationary magnetic field |
to explain Faraday's induction law and the surface phenomenon |
Skills - skills resulting from the course: |
to solve the basic configuration of stationary magnetic field, electrostatic field and current field |
to calculate capacity and inductance for the basic geometric arrangements |
to solve the forces in the electric and magnetic fields |
to calculate the energy of the electric and magnetic fields |
to derive and determine forces and energies in the electric and magnetic fields |
Competences - competences resulting from the course: |
N/A |
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Assessment methods
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Knowledge - knowledge achieved by taking this course are verified by the following means: |
Combined exam |
Seminar work |
Test |
Skills - skills achieved by taking this course are verified by the following means: |
Combined exam |
Test |
Seminar work |
Competences - competence achieved by taking this course are verified by the following means: |
Combined exam |
Seminar work |
Test |
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Teaching methods
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Knowledge - the following training methods are used to achieve the required knowledge: |
Lecture |
Practicum |
Laboratory work |
Skills - the following training methods are used to achieve the required skills: |
Practicum |
Task-based study method |
Competences - the following training methods are used to achieve the required competences: |
One-to-One tutorial |
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