4 ECTS credits
110 u studietijd

Aanbieding 1 met studiegidsnummer 4016340ENR voor alle studenten in het 2e semester met een verdiepend master niveau.

Semester
2e semester
Inschrijving onder examencontract
Niet mogelijk
Beoordelingsvoet
Beoordeling (0 tot 20)
2e zittijd mogelijk
Ja
Onderwijstaal
Engels
Onder samenwerkingsakkoord
Onder interuniversitair akkoord mbt. opleiding
Faculteit
Faculteit Ingenieurswetenschappen
Verantwoordelijke vakgroep
Elektriciteit
Externe partnerinstelling(en)
Université libre de Bruxelles
Onderwijsteam
Rik Pintelon
Emanuele Garone (titularis)
Michel Kinnaert
Onderdelen en contacturen
0 contacturen Exam
24 contacturen Lecture
24 contacturen Practical exercises
Inhoud

This course describes basic concepts and techniques for the analysis and design of a number of advanced model based controllers: amongst others robust controllers (H-infinity), internal model controllers, and feedforward controllers. To limit the complexity of the maths, the course is limited to the simplest class of systems: linear single input single output systems. Moreover, the course does not put the emphasis on maths but on the hands on experience: design, implementation, and critical evaluation of the advanced controllers. Therefore the course also provides practical insight that is very useful to design and implement the controllers.

Collocated versus non-collocated control
- basics concepts of structure dynamics
- pros and cons of collocated control
- alternating poles and zeros close to the imaginary axis
- robust SISO control via root locus
- non-collocated control

Feedback control theory: stability, robustness, design goals
- 1-degree of freedom (DOF) and 2-DOF controllers
- closed loop stability
- robustness
- design using frequency response functions: sensitivity and complementary sensitivity functions
- loop shaping
- performance limits

Internal modal control
- basics and structure of internal model based controllers
- 1-DOF internal model controllers (IMC)
- application of IMC design and link with the design of PID controllers
- 2-DOF IMC
- application of IMC: Smith predictor for systems with a significant delay

Tracking control
- adding a reference input to the control scheme
- influence of this reference input on the design of the state variable estimator
- basics of tracking control
- design of a feedforward loop for non-minimum phase systems: zero phase error tracking control

Uncertainty models and robustness
- parametric robustness analysis
- basic perturbation model
- "small gain" theorem
- robustness of the stability of feedback systems
- robustness analysis via structured singular values
- combination of robustness of stability and performance
- design of H-infinity controllers: mixed sensitivity, choice weighting functions, use of Matlab

Studiemateriaal
Digitaal cursusmateriaal (Vereist) : Transparencies used during the course
Bijkomende info

-Transparencies used during the course. They contain enough details to be used as study material.



Complementary study material:

- references mentioned in the transparencies (papers, books, ...)

- G.F. Franklin, J.D. Powell, and A. Emami-Naeini (2002). Feedback control of dynamic systems, Fourth Edition, Upper Saddle river: Addison-Wesley.

- S. Skogestad, and I. Postlethwaite (2003). Multi-variable feedback control : analysis and design:  Chichester: John Wiley and Sons.

Leerresultaten

Algemene competenties

AIMS AND OBJECTIVES

Acquiring practical knowledge about advanced control of dynamic systems



FINAL REQUIREMENTS

Skills:

- design of (robust) model based controllers with accurate tracking properties

- computer aided identification and design of controllers, simulation of systems and controllers (Matlab Simulink)



Attitudes:

- keep the importance of the control objective in mind in each step of the design

- critical interpretation of the experimental and simulation results

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:

  • Group project met een wegingsfactor 1 en aldus 100% van het totale eindcijfer.

    Toelichting: Project in groups of 2 or 3 students covering the whole design cycle of a controller: design and elaboration of identification experiments; and choice, design, implementation, and validation of a controller.

Aanvullende info mbt evaluatie

Project in groups of 2 or 3 students covering the whole design cycle of a controller: design and elaboration of identification experiments; and choice, design, implementation, and validation of a controller.

Written and oral presentation of the project (transparencies may serve as written report).

The projects start at the beginning of the semester.

Presentation of the project at the end of the semester or during the examination period.

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: werktuigkunde-elektrotechniek: lucht- en ruimtevaart
Master in de ingenieurswetenschappen: werktuigkunde-elektrotechniek: voertuigtechnologie en transport
Master in de ingenieurswetenschappen: werktuigkunde-elektrotechniek: werktuigbouwkunde
Master in de ingenieurswetenschappen: werktuigkunde-elektrotechniek: energie
Master of Electromechanical Engineering: Mechatronics-Construction (enkel aangeboden in het Engels)
Master of Electrical Engineering: Standaard traject BRUFACE J (enkel aangeboden in het Engels)