FYSS6311 Fundamentals of Control Engineering (5 cr)

Study level:
Advanced studies
Grading scale:
0-5
Language:
English, Finnish
Responsible organisation:
Department of Physics
Curriculum periods:
2024-2025, 2025-2026, 2026-2027, 2027-2028

Description

  • Introduction of basic terms related to control engineering and examples systems involving components related to control engineering
  • Theory behind Lablace-transform, transfer function and block diagram presentation
  • Principles of mathematic modelling of dynamic systems 
  • Principles of frequency analysis, time domain analysis of control systems and stability analysis of systems
  • Basic controllers and their working principles, principles of compensation and design of system, introduction of modern control engineering theory and basic concepts 
  • The basic mathematic tools relevant to this course will be rehearsed within this course, the course is not mathematically difficult. There are large number of concepts within control engineering, and that can be sometimes confusing

Learning outcomes

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

  • present and explain descriptions and definitions of basic control engineering concepts, and describe the definitions of Laplace transform and its inverse transform.
  • solve simple single-variable control engineering problems and solve differential equations using Laplace transform. They can also derive transfer functions for single-variable systems described by linear constant coefficient differential equations.
  • use block diagram representation and block diagram transformations in determining the system's transfer function. They can present the difference between frequency function and transfer function and utilize graphical methods (pole-zero plot, Nyquist plot, and Bode plot) in the system's frequency analysis.
  • examine the stability of the system and determine, in simple cases, the limits of control parameters within which the system is stable. They can also list basic controllers and present their definitions in Laplace domain.
  • present the definitions of compensators and explain why they can stabilize the system's behavior. They can present the definition of modern control theory state-space representation and its basic concepts.
  • solve simple problems using state-space representation and use Matlab program in solving basic control engineering problems.

Description of prerequisites

  • Perus- ja aineopinnot sekä niihin liittyvä matematiikka

Literature

  • Ogata, Modern Control Engineering (5th Ed.), ISBN-13: 978-8120340107; ISBN: 978-8120340107

Completion methods

Method 1

Evaluation criteria:
Tentti ja harjoitustehtävät (80 % tentti, 20 % harjoitustehtävät).
Time of teaching:
Period 4
Select all marked parts

Method 2

Description:
Tämä suoritustapa on tarkoitettu opiskelijoille, joille suoritustapa 1 ei erityisistä syistä ole mahdollinen (esim. opetuskieli, asuminen muualla, suositus yksilöllisistä opintojärjestelyistä). Suoritustavasta on otettava yhteyttä opettajaan ennen kurssille ilmoittautumista.
Evaluation criteria:
Kirjatentti
Select all marked parts
Parts of the completion methods
x

Teaching (5 cr)

Type:
Participation in teaching
Grading scale:
0-5
Language:
English, Finnish
No published teaching
x

Independent study (5 cr)

Type:
Independent study
Grading scale:
0-5
Evaluation criteria:
Kirjatentti
Language:
English, Finnish
Study methods:

Itsenäinen opiskelu, kirjatentti. 

Teaching