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Lecturer(s)
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Zálabský Tomáš, Ing. Ph.D.
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Course content
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1. Scattering matrix, reciprocal and non-reciprocal circuits, shockless circuits 2. Conductors - coaxial, microstrip, coplanar, waveguide 3. Waveguide integrated into the substrate - SIW 4. Impedance transformers 5. Resonators from line sections, planar and dielectric resonators, cavity resonators, excitation of resonators 6. Power dividers, directional couplers 7. Microwave amplifiers and phase shifters, shockless loads 8. Microwave filters I 9. Microwave filters II 10. Microwave active elements - klystron, magnetron, semiconductor elements 11. Microwave oscillators - design and tuning 12. Microwave amplifiers -design and parameters.
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Learning activities and teaching methods
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Monologic (reading, lecture, briefing), Dialogic (discussion, interview, brainstorming), Laboratory work
- Participation in classes
- 54 hours per semester
- Home preparation for classes
- 30 hours per semester
- Contact teaching
- 54 hours per semester
- Preparation for laboratory work and processing of results
- 12 hours per semester
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Learning outcomes
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The course is focused on the study of microwave circuits. First, students are introduced to the basic parameters of microwave circuits and the basic microwave transmission lines and structures. Another part of the course is devoted to the design of microwave couplers, power dividers, attenuators and phase shifters. The key part of the course is devoted to microwave filters, with emphasis on their theoretical description and construction. Another part of the course is devoted to active microwave circuits, oscillators and amplifiers. The last part of the course is focused on an introduction to the issue of the substrate integrated waveguide.
Upon completion of this course, the student will be familiar with basic high-frequency lines. In addition, the student will be able to design standard passive microwave elements and will be familiar with the design and parameters of active microwave elements. Finally, the student will be competent to perform measurements of microwave elements and to properly display and evaluate the measured results.
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Prerequisites
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Basic knowledge of high school mathematics, integral and differential calculus.
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Assessment methods and criteria
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Oral examination, Written examination
The student must demonstrate an understanding of the solved problems during the semester and during the final exam. The specific requirements will be communicated to the students by the teacher in the first week of the semester.
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Recommended literature
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Belous, A. Handbook of microwave and radar engineering. Cham, Switzerland: Springer Nature, 2021. ISBN 978-3-030-58701-7.
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Černohorský, D. Analýza a optimalizace mikrovlnných struktur. Brno: VUTIUM, 1999. ISBN 80-214-1512-6.
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Hoffmann, K. Aktivní mikrovlnné obvody. Praha: Česká technika ? nakladatelství ČVUT, 2009. ISBN 978-80-01-04226-7.
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Hoffmann, K., Hudec, P. a Sokol, V. Aktivní mikrovlnné obvody. 2. vyd.. Praha: Česká technika ? nakladatelství ČVUT, 2009. ISBN 978-80-01-04226-7.
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Mazánek, M. Základy antén, šíření vln a mikrovlnné techniky. Praha: Česká technika ? nakladatelství ČVUT, 2008. ISBN 978-80-01-03997-7.
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Oppl, L. Úvod do mikrovlnné techniky: sbírka příkladů. Praha: Vydavatelství ČVUT, 2004. ISBN 80-01-030547.
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Pozar, D. M. Microwave engineering. 4th ed.. Hoboken: Wiley, 2012. ISBN 978-0-470-63155-3.
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Vrba, J. Úvod do mikrovlnné techniky. Praha: Česká technika ? nakladatelství ČVUT, 2007. ISBN 978-80-01-036709.
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Zálabský, T. Elektronická opora k předmětu: Mikrovlnné obvody. 2024.
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