|
|
Main menu for Browse IS/STAG
Course info
KEP / ED
:
Course description
Department/Unit / Abbreviation
|
KEP
/
ED
|
Academic Year
|
2023/2024
|
Academic Year
|
2023/2024
|
Title
|
Electrodynamics
|
Form of course completion
|
Exam
|
Form of course completion
|
Exam
|
Accredited / Credits
|
Yes,
4
Cred.
|
Type of completion
|
Combined
|
Type of completion
|
Combined
|
Time requirements
|
Lecture
2
[Hours/Week]
Tutorial
2
[Hours/Week]
|
Course credit prior to examination
|
Yes
|
Course credit prior to examination
|
Yes
|
Automatic acceptance of credit before examination
|
No
|
Included in study average
|
YES
|
Language of instruction
|
Czech, English
|
Occ/max
|
|
|
|
Automatic acceptance of credit before examination
|
No
|
Summer semester
|
0 / -
|
0 / -
|
0 / -
|
Included in study average
|
YES
|
Winter semester
|
101 / -
|
0 / -
|
2 / -
|
Repeated registration
|
NO
|
Repeated registration
|
NO
|
Timetable
|
Yes
|
Semester taught
|
Winter semester
|
Semester taught
|
Winter semester
|
Minimum (B + C) students
|
10
|
Optional course |
Yes
|
Optional course
|
Yes
|
Language of instruction
|
Czech, English
|
Internship duration
|
0
|
No. of hours of on-premise lessons |
|
Evaluation scale |
1|2|3|4 |
Periodicity |
každý rok
|
Evaluation scale for credit before examination |
S|N |
Periodicita upřesnění |
|
Fundamental theoretical course |
Yes
|
Fundamental course |
No
|
Fundamental theoretical course |
Yes
|
Evaluation scale |
1|2|3|4 |
Evaluation scale for credit before examination |
S|N |
Substituted course
|
None
|
Preclusive courses
|
N/A
|
Prerequisite courses
|
N/A
|
Informally recommended courses
|
N/A
|
Courses depending on this Course
|
KEP/SBTE
|
Histogram of students' grades over the years:
Graphic PNG
,
XLS
|
Course objectives:
|
Electromagnetic field theory-Maxwell's equations in integral and differential form, potential equations,solution of boundary problems, usage of computer programs for solution of physical fields. The basic laws of non-sationary electromagnetic field. Physical basis of skineffect, electromagnetic wave propagation.
|
Requirements on student
|
Credits (the seminars are obligatory)
- 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.
|
Content
|
1. Non-stationary Maxwell equations in integral and differential form. Electrodynamic potentials.
2. Maxwell equations for the time harmoniously variable electromagnetic field. Energy balance of the electromagnetic field.
Poynting vector.
3. Special methods for solving fields. Integral expressions for potentials. Mirroring method. Calculation of operating parameters (resistance, capacity, inductance) for typical configurations.
4. Boundary problems and their solution. Stationary form of partial differential equations for potential.
5. Analytical solution of simple boundary problems in planar, axial and spherical symmetry.
6. Numerical solution of boundary problems. Finite Difference Method.
7. Advanced methods for solving boundary problems.
8. Homogeneous transmission line. Basic equation for space-time distribution of voltage and current.
9. Homogeneous transmission line in steady harmonic state.
10. Electromagnetic waves.
11. Spreading of planar, cylindrical and spherical waves through open space. Wave impact on the interface.
12. Basic types of antennas. Near and far field. Radiation characteristics.
13. Basic types of waveguides, characteristic oscillations.
|
Activities
|
|
Fields of study
|
|
Guarantors and lecturers
|
-
Guarantors:
Prof. Ing. Pavel Karban, Ph.D. ,
-
Lecturer:
Prof. Ing. Zdeňka Benešová, CSc. (100%),
Prof. Ing. Ivo Doležel, CSc. (100%),
Ing. Roman Hamar, Ph.D. (100%),
Prof. Ing. Pavel Karban, Ph.D. (100%),
-
Tutorial lecturer:
Prof. Ing. Pavel Karban, Ph.D. (100%),
Ing. Jan Kaska (100%),
Ing. Marcela Ledvinová, Ph.D. (60%),
Doc. Ing. David Pánek, Ph.D. (20%),
Ing. Iveta Petrášová (20%),
Ing. Ondřej Sodomka (100%),
|
Literature
|
-
Recommended:
Mayer, Daniel. Aplikovaný elektromagnetizmus : úvod do makroskopické teorie elektromagnetického pole pro elektrotechnické inženýry. 1. vyd. České Budějovice : Kopp, 2012. ISBN 978-80-7232-424-8.
-
Recommended:
John David Jackson. Classical Electrodynamics. 2009. ISBN 978-8126510948.
-
Recommended:
Edward M. Purcell. Electricity and Magnetism. 2013. ISBN 978-1107014022.
-
Recommended:
Sedlák, Bedřich; Štoll, Ivan. Elektřina a magnetismus. První elektronické vydání (Čtvrté vydání, v Nakladatelství Karolinum třetí). 2017. ISBN 978-80-246-3146-2.
-
Recommended:
Halliday, David; Resnick, Robert,; Walker, Jearl,; Dub, Petr. Fyzika. 2., přeprac. vyd. Brno : VUTIUM, 2013. ISBN 978-80-214-4123-1.
-
Recommended:
David J. Griffiths. Introduction to Electrodynamics. 2017. ISBN 978-1108420419.
-
Recommended:
Benešová, Zdeňka; Mayer, Daniel. Základní příklady z teorie elektromagnetického pole. 1. vyd. Plzeň : Západočeská univerzita, 2001. ISBN 80-7082-818-8.
-
On-line library catalogues
|
Time requirements
|
All forms of study
|
Activities
|
Time requirements for activity [h]
|
Preparation for laboratory testing; outcome analysis (1-8)
|
5
|
Undergraduate study programme term essay (20-40)
|
20
|
Preparation for formative assessments (2-20)
|
5
|
Preparation for an examination (30-60)
|
30
|
Total
|
60
|
Combined form of study
|
Activities
|
Time requirements for activity [h]
|
E-learning [dáno e-learningovým kurzem]
|
36
|
Contact hours
|
16
|
Total
|
52
|
Full-time form of study
|
Activities
|
Time requirements for activity [h]
|
Contact hours
|
52
|
Total
|
52
|
|
Prerequisites
|
Knowledge - students are expected to possess the following knowledge before the course commences to finish it successfully: |
control the basic laws and principles of the stationary electromagnetic field |
control the basis of vector analysis, calculus, differential equations |
Skills - students are expected to possess the following skills before the course commences to finish it successfully: |
to control commonly available information and communication technique |
Competences - students are expected to possess the following competences before the course commences to finish it successfully: |
N/A |
N/A |
N/A |
|
Learning outcomes
|
Knowledge - knowledge resulting from the course: |
characterize the physical nature of electromagnetic phenomena |
to explain basic methods for the analysis of electromagnetic phenomena |
summarize the underlying phenomena of the non-stationary electromagnetic field |
describe wave processes on the line and in the free space |
Skills - skills resulting from the course: |
to work with a computer program for the analysis of electromagnetic phenomena |
Competences - competences resulting from the course: |
N/A |
|
Assessment methods
|
Knowledge - knowledge achieved by taking this course are verified by the following means: |
Combined exam |
Test |
Seminar work |
Skills - skills achieved by taking this course are verified by the following means: |
Combined exam |
Seminar work |
Individual presentation at a seminar |
Competences - competence achieved by taking this course are verified by the following means: |
Skills demonstration during practicum |
|
Teaching methods
|
Knowledge - the following training methods are used to achieve the required knowledge: |
Lecture |
Practicum |
Skills - the following training methods are used to achieve the required skills: |
Lecture |
Practicum |
Task-based study method |
Competences - the following training methods are used to achieve the required competences: |
Lecture |
Practicum |
|
|
|
|