3 ECTS credits
90 u studietijd

Aanbieding 1 met studiegidsnummer 4007427EER voor alle studenten in het 1e semester met een verdiepend master niveau.

Semester
1e semester
Inschrijving onder examencontract
Mogelijk
Beoordelingsvoet
Beoordeling (0 tot 20)
2e zittijd mogelijk
Ja
Inschrijvingsvereisten
Students of the Master in Electrical Engineering who want to register for this ‘Option package’ course must have successfully accomplished or must at least be registered for 30 ECTS of compulsory courses of the common core.
Onderwijstaal
Engels
Onder samenwerkingsakkoord
Onder interuniversitair akkoord mbt. opleiding
Faculteit
Faculteit Ingenieurswetenschappen
Verantwoordelijke vakgroep
Elektriciteit
Onderwijsteam
Ivan Markovsky (titularis)
Onderdelen en contacturen
0 contacturen Exam
18 contacturen Lecture
42 contacturen Self study
Inhoud

Goal: to give an intuitive insight in the behaviour of nonlinear systems. For that purpose we first provide the attendees with a theoretical framework that will be used next to develop a number of tools that can be easily used in practice to characterize nonlinear systems.


A theoretic framework
- Impact of the choice of excitation and the choice of convergence criterion
- Volterra representation of nonlinear systems
- Nonparametric representation of nonlinear systems
- Best linear approximation of nonlinear systems
- Stochastic nonlinear contributions


Practical applications
- Detection, qualification and quantification of nonlinear distortions.
- Measurement of transfer functions in the presence of nonlinear distortions.
- Measurement of Volterra kernels in time and frequency domain.
- Nonparametric measurement of nonlinear systems.

Studiemateriaal
Cursustekst (Vereist) : Measuring and Modelling of Nonlinear Systems, Handouts (English) are given to the students.
Bijkomende info

Course notes are made available during the lessons.

Leerresultaten

Algemene competenties

Goal: to give an intuitive insight in the behavior of nonlinear systems. For that purpose we first provide the attendees with a theoretical framework that will be used next to develop a number of tools that can be easily used in practice to characterize nonlinear systems.

The students understand the impact of the choice of the excitation and the convergence criterion: the students design a proper experiment. The choices are motivated from theoretical, practical, and application point of view.

The students can detect, qualify and quantify nonlinear distortions

The students use the Volterra representation of nonlinear systems as a general framework: the students can create a nonparametric representation of a nonlinear system. They understand the advantages and disadvantages of their choices. They can apply Volterra theory to analyse cascaded nonlinear systems, including the pre- and post-inverse.

The students can work with the best linear approximation of nonlinear systems: the students are able to apply linear modelling techniques in the presence of nonlinear distortions. They understand the impact of the nonlinear distortions on the properties of the framework using the concept of systematic and stochastic contributions.

The students are able to make initial choices to build nonparametric models using nonlinear state space or block oriented models.

This course contributes to the following programme outcomes of the Master in Electronics and Information Technology Engineering:

The Master in Engineering Sciences has in-depth knowledge and understanding of
3. the advanced methods and theories to schematize and model complex problems or processes

The Master in Engineering Sciences can
6. correctly report on research or design results in the form of a technical report or in the form of a scientific paper
9. work in an industrial environment with attention to safety, quality assurance, communication and reporting
11. think critically about and evaluate projects, systems and processes, particularly when based on incomplete, contradictory and/or redundant information

The Master in Engineering Sciences has
12. a creative, problem-solving, result-driven and evidence-based attitude, aiming at innovation and applicability in industry and society

The Master in Electronics and Information Technology Engineering:
17. Has an active knowledge of the theory and applications of electronics, information and communication technology, from component up to system level.
18. Has a profound knowledge of either (i) nano- and opto-electronics and embedded systems, (ii) information and communication technology systems or (iii) measuring, modelling and control.
19. Has a broad overview of the role of electronics, informatics and telecommunications in industry, business and society.
20. Is able to analyze, specify, design, implement, test and evaluate individual electronic devices, components and algorithms, for signal-processing, communication and complex systems.
21. Is able to model, simulate, measure and control electronic components and physical phenomena.
 

 

Beoordelingsinformatie

De beoordeling bestaat uit volgende opdrachtcategorieën:
Examen Mondeling bepaalt 100% van het eindcijfer

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

  • oral exam met een wegingsfactor 1 en aldus 100% van het totale eindcijfer.

Aanvullende info mbt evaluatie

oral exam

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: elektronica en informatietechnologie: Standaard traject
Master of Photonics Engineering: On campus traject (enkel aangeboden in het Engels)
Master of Photonics Engineering: Online/Digital traject (enkel aangeboden in het Engels)
Master of Electrical Engineering: Standaard traject BRUFACE J (enkel aangeboden in het Engels)