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Lecturer(s)
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Lepka Olaf, Ing. Ph.D.
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Večerek Lukáš, Ing. Ph.D.
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Horáček Štěpán, Ing. Ph.D.
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Course content
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1. Introduction to space technologies and their usage. 2. Analysis of the conditions under which space technologies are exposed. 3. Limiting the impact of the cosmic environment on technologies and systems. 4. Introduction to the technical solution of basic space technologies. 5. Analysis of the technical solution of selected basic space technologies I. (COM) 6. Analysis of the technical solution of selected basic space technologies II (OBDH, OBC) 7. Analysis of the technical solution of selected basic space technologies III. (EPS) 8. Analysis of the technical solution of selected basic space technologies IV (ADCS, AOCS) 9. Testing of space technologies in ground laboratories. 10. Testing of space technologies using stratospheric balloons and sounding rockets. 11. Invited lecture from space related industry and science I. 12. Invited lecture from space related industry and science II. 13. Seminar work - presentations of students.
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Learning activities and teaching methods
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Laboratory work, Lecture
- Contact hours
- 26 hours per semester
- Practical training (number of hours)
- 26 hours per semester
- Graduate study programme term essay (40-50)
- 20 hours per semester
- Preparation for an examination (30-60)
- 30 hours per semester
- Presentation preparation (report) (1-10)
- 2 hours per semester
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| prerequisite |
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| Knowledge |
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| to summarize the basic knowledge of secondary school physics in the field of electromagnetism, electromagnetic waves, sound and motion mechanics |
| explain the principle of basic analog and digital electronic circuits |
| explain the basic concepts of telecommunication technology |
| Skills |
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| to use and understand technical literature written in English |
| implement calculations and simulations in Matlab |
| Competences |
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| N/A |
| N/A |
| learning outcomes |
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| Knowledge |
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| describe the conditions of operation of electronic subsystems in space |
| describe the principles of basic satellite electronic subsystems |
| explain the process of development and testing of electronic technologies for space |
| Skills |
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| propose appropriate types of measures to reduce undesirable impacts of space environment |
| select a suitable solution for satellite subsystems based on their technical specifications and mission requirements |
| perform an analysis of the technical feasibility of the mission under specified conditions |
| calculate the energy budget of the satellite power supply |
| calculate the radio link budget of the satellite communication system |
| Competences |
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| N/A |
| teaching methods |
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| Knowledge |
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| Lecture supplemented with a discussion |
| Interactive lecture |
| Laboratory work |
| Project-based instruction |
| Students' portfolio |
| Skills |
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| Lecture supplemented with a discussion |
| Laboratory work |
| Project-based instruction |
| Students' portfolio |
| Competences |
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| Self-study of literature |
| Laboratory work |
| Project-based instruction |
| Students' portfolio |
| assessment methods |
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| Knowledge |
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| Combined exam |
| Skills |
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| Combined exam |
| Competences |
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| Individual presentation at a seminar |
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Recommended literature
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European Space Agency. ESA Bulletin.
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IEEE. Proceedings of the IEEE - Small satellites special issue. 2018.
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International Academy of Astronautics. Acta astronautica.
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International School of Advanced Studies (SISSA) and IOP Publishing. Journal of Instrumentation.
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