Imaging Systems in Medicine 2 - Interaktive Studienpläne der TU Ilmenau
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| Modulinformationen zu Imaging Systems in Medicine 2 im Studiengang Master Biomedical Engineering by Research 2026 | ||
|---|---|---|
| Modulnummer | 201263 | |
| Prüfungsnummer | 220501 | |
| Fakultät | Fakultät für Informatik und Automatisierung | |
| Fachgebietsnummer | 2221 (Biomedizinische Technik) | |
| Modulverantwortliche(r) | Dr. Dunja Jannek | |
| Turnus | Sommersemester | |
| Sprache | Englisch | |
| Leistungspunkte | 5 | |
| Präsenzstudium (h) | 28 | |
| Selbststudium (h) | 122 | |
| Verpflichtung | Wahlmodul | |
| Abschluss | Prüfungsleistung mit mehreren Teilleistungen | |
| Details zum Abschluss | Das Modul Imaging Systems in Medicine 2 mit der Prüfungsnummer 220501 schließt mit folgenden Leistungen ab:
A documented instruction is required each semester in order to carry out laboratory experiments. | |
| Link zum Moodle-Kurs | ||
| Lehrende | Dr. Dunja Jannek | |
| Anmeldemodalitäten für alternative PL oder SL | ||
| max. Teilnehmerzahl | ||
| Vorkenntnisse | Mathematics, Physics, Basic Concepts of Imaging Systems in Medicine, Signal Processing, Measurement Technology | |
| Lernergebnisse und erworbene Kompetenzen | Students are familiar with the subject, aim and methods of imaging systems, including their position and relationships in biomedical engineering. They understand the concept, causes and effects of local dynamics. They adapt known methods for describing time-dynamic systems for multidimensional, location-dependent signals. Students can successfully apply these methods to analyze medical imaging systems across all stages, including the eye as receiver, and are able to critically evaluate the possibilities and limitations of the image signal transmission process. Students are able to apply these description methods using the example of two imaging systems presented (magnetic resonance imaging, ultrasound systems). They know the clinical benefits of the imaging systems including their task relevance, limitations and risks and can apply the various methodological approaches in their experimental work. Through the associated practical experiments, students are able to work independently with an experimental computer tomograph and with a modern ultrasound B-scan system and to evaluate the transmission behavior experimentally. They are be able to recognize the relationships between the physical interaction effects used and technical components as well as image errors and the limits of achievable image quality. They show interest in experimental work and know and observe the radiation protection regulations and other safety regulations. Students are familiar with the complex requirements of imaging systems in medicine. They are able to take part in subject-specific discussions and answer questions addressed to them on the basis of their acquired knowledge. Students learn to accept criticism of their opinion and to allow other opinions. | |
| Inhalt | Signal Transmission Behaviour: Characteristics of the elementary imaging system, extension of the concept of dynamics, system classes, operator properties, heuristic approach, complete description, coordinate transformation, static behaviour, contrast transfer, spatial dynamics, decomposition into impulses, decomposition into sinusoidal oscillations, noise, transmission of noise, effect on detail recognition, sampling systems, spatial sampling, 2D sampling theorem, undersampling, aliasing, slice reconstruction methods, model approach, filtered back projection, measurement of transmission behaviour, statement of transmission behaviour, the eye as image receiver. Magnetic resonance imaging (MRI): Physical interaction effects, microscopic nuclear magnetisation, macroscopic nuclear magnetisation, relaxation, nuclear resonance, determination of relaxation times, MR imaging, spatial resolution: gradient fields, principle, possibilities, single layer method, scanner device technology. Diagnostic ultrasound applications: Physical interaction effects, sound, ultrasound, sound propagation at boundary layers, echo principle, Doppler principle, ultrasound generation, ultrasound conversion; Imaging, echo pulse technique, A scan, B scan, M scan, Doppler, colour Doppler, transmission behaviour, spatial resolution, temporal resolution, disturbance variables, noise. Experimental work: 1. Computed Tomography reconstruction methods Ultrasound Imaging | |
| Medienformen und technische Anforderungen bei Lehr- und Abschlussleistungen in elektronischer Form | Presentations, Handout, Moodle | |
| Literatur |
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| Lehrevaluation | ||