Kód | Zakončení | Kredity | Rozsah | Jazyk výuky |
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F7DIMMS | ZK | 20P+8C | anglicky |
The aim of the course is to introduce the students with basic knowledge (physical and technical background, basic measurement principles and application examples in diagnostics and therapy) of this innovative field of research being on the cusp to commercialization and clinical practice.
In the case of foreign lecturers, there will be a weeklong block of intensive contact education for the number of students at least five. If the number of students is less than five, the course will be self-study with consultations using VoIP (e.g. Skype) and a contact 1-or 2-day seminar. The contact seminar will take place at the FBMI or at the home institution of a foreign lecturer. The subjects are concluded by an oral examination. The student must elaborate a paper on a given topic together with the exam in case of the controlled self-study.
Two laboratory exercises are required for admission to the exam (attested by a protocol signed by the student, the tutor and the supervisor of the course).
The protocols will be archived in the Department for Doctoral Studies.
Brief Syllabus of Lectures:
1.Introduction: Presentation of current and perspective applications of microwave sensing in diagnostics and therapy
2.Physical basics: microwaves in the spectrum of electromagnetic waves, effects and interaction of electromagnetic waves in media, polarization, relative permittivity, relative permeability, Debye relaxation model, Cole-Cole model
3.Propagation of electromagnetic waves in media, frequency dependence of attenuation, losses, penetration depth, wave length and propagation speed
4.Transmission and reflection at dielectric interfaces, plane electromagnetic wave, refraction, Snell’s law, Brewster’s angle, angle of total reflection, spherical wave fronts, Huygens–Fresnel principle. Conducted wave propagation, wave guides, wave impedance, reflection coefficient
5.Measurement of s-parameters, network analyzer, 3- and 8-term calibration,
6.Dielectric spectroscopy, calibration procedure, frequency and temperature dependent permittivity measurement of tissue and tissue mimicking phantom materials, concentration measurement of two-substance mixtures
7.Antennas and components for microwave sensing, short dipoles, horn antennas, patch antennas, radiation pattern, gain, reciprocity, near field vs. far field, directional couplers
8.Ultra-wideband sensing technologies, impulse based technology, M-sequence technology, ultra-wideband radar, radar equation
9.Beamforming / migration algorithms, imaging of static objects, detection of moving objects, remote vital data acquisition, motivation and physiological background of medical microwave imaging (breast imaging, stroke classification)
10.Surface reconstruction based on Boundary Scattering Transform
Brief Syllabus of Exercises:
1.Development and implementation of a beamforming algorithm, application for imaging of a breast phantom data set
2.Localization of a person and remote vital sign detection (acquisition of breathing and pulse signal) based on UWB radar
The aim of the course is to introduce the students with basic knowledge (physical and technical background, basic measurement principles and application examples in diagnostics and therapy) of this innovative field of research being on the cusp to commercialization and clinical practice.
Required:
1.J. Sachs, Handbook of ultra-wideband short-range sensing: theory, sensors, applications. - Weinheim: Wiley-VCH, 2012, ISBN 9783527651818
Recommended:
1.Harry M. Jol, Ground Penetrating Radar Theory and Applications, Elsevier Science, 2009, ISBN 978-0-444-53348-7
2.Zwick, T., Wiesbeck, W., Timmermann, J., & Adamiuk, G, Ultra-wideband RF System Engineering (EuMA High Frequency Technologies Series). Cambridge: Cambridge University Press, 2013, ISBN 9781139058957
Modul F
Příloha | Velikost |
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Radar Technology in Medicine | 12.67 MB |