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Lecturer(s)
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Svobodová Helena, Ing. Ph.D.
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Grossl Jiří, prof. Ing. Ph.D.
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Marák Marek, doc. Ing. Ph.D.
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Sitta Pavel, Ing. Ph.D.
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Fessl Jiří, Ing.
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Hraba Tomáš, Ing.
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Course content
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1. Modeling in electrical applications, definition of basic concepts. 2. Numerical methods - overview (ODE, PDE, FDM, FEM, integral equations). 3. Electrostatic and current field, differential equations, boundary conditions, application examples. 4. Electromagnetic harmonic field (low frequencies), differential equations, boundary conditions, application examples. 5. Electromagnetic harmonic field (high frequency), differential equations, boundary conditions, application examples. 6. Homogeneous line, harmonic steady state, shock phenomena. 7. Temperature field, differential equations, boundary conditions, application examples. 8. Associated problems of electromagnetic and temperature field, forms of association. 9. Structural analysis, modal analysis, vibrations 10. Thermoelastic deformation - coupling of structural analysis and heat transfer, application examples. 11. Results analysis and model calibration. 12. Optimization - methods, local and global algorithms, goal functions. 13. Optimization - multicriterial tasks, constraints, solvability and usability.
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Learning activities and teaching methods
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Laboratory work, Students' self-study, Lecture
- Presentation preparation (report) (1-10)
- 16 hours per semester
- Preparation for laboratory testing; outcome analysis (1-8)
- 4 hours per semester
- Contact hours
- 52 hours per semester
- Preparation for formative assessments (2-20)
- 6 hours per semester
- Preparation for an examination (30-60)
- 30 hours per semester
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| prerequisite |
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| Knowledge |
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| to master the basic methods of electromagnetic field analysis and computer solution of physical fields |
| to explain the basics of electromagnetic, electrostatic and current field theory, temperature field and structural mechanics |
| Skills |
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| model the behavior of typical devices used in electrical engineering |
| Competences |
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| N/A |
| N/A |
| learning outcomes |
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| Knowledge |
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| be familiar with the basic methods of computer solution of physical fields |
| Skills |
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| formulate selected problems using boundary problems for potential including boundary conditions |
| analyze simple practical problems in the field of electromagnetic and temperature field |
| solve, using a computer, simple practical problems from the field of electromagnetic and temperature field |
| verify experimentally obtained results |
| teaching methods |
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| Knowledge |
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| Lecture |
| Practicum |
| Task-based study method |
| Skills |
|---|
| Laboratory work |
| One-to-One tutorial |
| assessment methods |
|---|
| Knowledge |
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| Combined exam |
| Seminar work |
| Skills |
|---|
| Combined exam |
| Skills demonstration during practicum |
| Test |
| Seminar work |
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Recommended literature
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Carlos A. Smith, Scott W. Campbell. A First Course in Differential Equations, Modeling, and Simulation. 2016. ISBN 148225722X.
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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.
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Paul J. Nahin. Transients for Electrical Engineers: Elementary Switched-Circuit Analysis in the Time and Laplace Transform Domains. 2018. ISBN 3319775979.
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Randy Haupt. Antenna Arrays: A Computational Approach. 2010. ISBN 0470407751.
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