Biomedical Signals and Images

3 ECTS credits
80 u studietijd

Aanbieding 1 met studiegidsnummer 4019776DNR voor alle studenten in het 1e semester met een inleidend master niveau.

Semester

1e semester

Inschrijving onder examencontract

Niet mogelijk

Beoordelingsvoet

Beoordeling (0 tot 20)

2e zittijd mogelijk

Onderwijstaal

Engels

Faculteit

Faculteit Ingenieurswetenschappen

Verantwoordelijke vakgroep

Elektronica en Informatica

Onderwijsteam

Jef Vandemeulebroucke (titularis)

Onderdelen en contacturen

18 contacturen Hoorcollege
18 contacturen Werkcolleges, practica en oefeningen

Inhoud

Goal of the course

The goal of this course is to provide an introduction to the field of biomedical signals and images. An overview is given the principle modalities of biomedical signals and images, along with the basic concepts of the most commonly used signal and imaging equipment. Popular signal and image processing techniques are presented with an emphasis on common applications in the biomedical field.

Starting from basic concepts of one-dimensional and multi-dimensional digital signal processing, and fundamental physiological and physical principles, the major bio-electric signal acquisition and imaging equipment are explained. The performances and limitations of these techniques are also discussed such that image quality (noise, scatter, artifacts, etc.) can be clarified and identified. Next, common operations in biomedical signal and image processing will be presented, such as image enhancement, segmentation, feature extraction registration and visualization of medical images.

Contents

Introduction to signals, images and digital signal processing: sampling and quantization, linear and stationary systems, convolution and correlation, filtering, Fourier transform, Nyquist criterion
Bio-electrical signals (ECG,EEG): principle, instrumentation, acquisition and analysis
Biomedical images (X-Ray, CT, MRI, US, SPECT and PET): principle, instrumentation, acquisition and image formation
Biomedical image enhancement, filtering and segmentation
Feature extraction and quantification
Biomedical image registration and visualization

Practical sessions and exercises:

The lectures are supported by 4 practical sessions, covering topics from the lectures:

Introduction to signals, images and digital signal processing
Biomedical signal processing for ECG and EEG
Biomedical image enhancement, filtering and segmentation
Feature extraction and quantification

Studiemateriaal

Digitaal cursusmateriaal (Vereist) : Slides presented during lectures, Jef Vandemeulebroucke
Handboek (Aanbevolen) : Biomedical Signal and Image Processing, Kayvan Najarian, Robert Splinter, 2de, CRC Press, 9781439870334, 2012

Bijkomende info

Lectures will cover the theorectical part of the course. Practical sessions will consist of exercises in which the concepts seen during the lectures are applied. Practical sessions will be guided by assistants. Reports on the practical sessions can be finalized afterwards.

Leerresultaten

General Competences

After completing this course, the student will be able to:

Apply the basic principles of digital signal processing, load digital signals and images, perform common operations and visualize them
Explain the sources of bio-electrical signals, understand the principle of signal acquisition and carry out typical signal analysis operations
List the different types of biomedical image modalities, differentiate the underlying physical principle, and summarize the instrumentation, acquisition and image formation
Explain the principle of image enhancement, filtering and segmentation; and apply those to biomedical images
Explain the goal of feature extraction and quantification, and compare the outcome for different types of images
Explain the process of biomedical image registration and visualization, and select the suitable settings depending on the situation

This course contributes to the following programme outcomes of the Master in Applied Computer Sciences:

MA_A: Knowledge oriented competence

1. The Master in Engineering Sciences has in-depth knowledge and understanding of exact sciences with the specificity of their application to engineering
3. The Master in Engineering Sciences has in-depth knowledge and understanding of the advanced methods and theories to schematize and model complex problems or processes
4. The Master in Engineering Sciences can reformulate complex engineering problems in order to solve them (simplifying assumptions, reducing complexity)
6. The Master in Engineering Sciences can correctly report on research or design results in the form of a technical report or in the form of a scientific paper
8. The Master in Engineering Sciences can collaborate in a (multidisciplinary) team

MA_B: Attitude

12. The Master in Engineering Sciences has a creative, problem-solving, result-driven and evidence-based attitude, aiming at innovation and applicability in industry and society
15. The Master in Engineering Sciences has the flexibility and adaptability to work in an international and/or intercultural context

MA_C: Specific competence

17. The Master in Applied Computer Sciences has a thorough understanding of the underlying physical principles and the functioning of electronic and photonic devices, of sensors and actuators and is able to use them to conceive information processing systems and more specifically systems of systems
19, The Master in Applied Computer Sciences has knowledge of and is able to use advanced processing methods and tools for the analysis of (big) data in different application domains
26. The Master in Applied Computer Sciences can apply his/her acquired knowledge and skills for designing smart city or digital health dedicated systems of systems.
27. The Master in Applied Computer Sciences is aware of and critical about the impact of ICT on society.

Beoordelingsinformatie

De beoordeling bestaat uit volgende opdrachtcategorieën:
Examen Mondeling bepaalt 65% van het eindcijfer

Examen Praktijk bepaalt 35% van het eindcijfer

Binnen de categorie Examen Mondeling dient men volgende opdrachten af te werken:

Oral exam theory met een wegingsfactor 1 en aldus 65% van het totale eindcijfer.

Toelichting: Oral exam with written preparation. After the questions are given, students will be given time to prepare the answers on paper, before explaining these during oral examination.

Binnen de categorie Examen Praktijk dient men volgende opdrachten af te werken:

Report on the exercises met een wegingsfactor 1 en aldus 35% van het totale eindcijfer.

Toelichting: Reports describing the results on the assignments given during the practical sessions will be evaluated. Evaluation will be based on the correctness of the performed assignments, the answers to the questions and the completeness of the reports

Aanvullende info mbt evaluatie

Students must participate to the oral exam and complete the reports on the practical sessions. Students must pass both parts (oral exam and practical sessions) in order to pass the course. An exemption for either part can be obtained for the second session, if a passing grade was obtained for that part in the first session.

Toegestane onvoldoende

Kijk in het aanvullend OER van je faculteit na of een toegestane onvoldoende mogelijk is voor dit opleidingsonderdeel.

Academische context

Deze aanbieding maakt deel uit van de volgende studieplannen:
Master in de ingenieurswetenschappen: toegepaste computerwetenschappen: Standaard traject
Master of Applied Sciences and Engineering: Applied Computer Science: Standaard traject (enkel aangeboden in het Engels)
Master in Applied Sciences and Engineering: Computer Science: Artificial Intelligence (enkel aangeboden in het Engels)
Master in Applied Sciences and Engineering: Computer Science: Multimedia (enkel aangeboden in het Engels)
Master in Applied Sciences and Engineering: Computer Science: Software Languages and Software Engineering (enkel aangeboden in het Engels)
Master in Applied Sciences and Engineering: Computer Science: Data Management and Analytics (enkel aangeboden in het Engels)