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Control, Servo System and Microcontroller TechniquesLaajuus (5 cr)

Code: 5K00DL39

Credits

5 op

Objectives

The student understands the significance of sustainable development when designing servo systems for machine automation applications.
The student understands the importance of cost-effectiveness, quality and safety when designing motion control applications.
The student is able to dimension and select the components for typical machine automation servo systems.
The student masters the basics of control engineering.
The student is able to exploit a modeling and simulation software for designing and analyzing a servo system.
The student is capable of designing a basic control structure for a servo system.

Content

In the course, the structure and different implementation approaches of servo systems for motion control systems are studied.

The mathematical modeling of dynamic systems based on differential equations are studied as well as the modeling in the frequency domain obtained by Laplace transformation.

The basic of control engineering, analysis methods of dynamic systems and basic controller structures of servo systems are considered.

The course includes a project task which involves dimensioning, modeling, simulation and control design of a servo system with a CAD-software.

Assessment criteria, satisfactory (1-2)

The student adequately masters the basics of control and servo technology. The student is able to dimension a simple servo system and select components for it, assisted if necessary. The student is able to utilize modeling and simulation software assisted in the analysis of servo systems. Can tune the controller to a simple system.

Assessment criteria, good (3-4)

The student masters the basics of control and servo technology well. The student is able to dimension a simple servo system and select components for it independently. The student is able to utilize modeling and simulation software in the analysis of servo systems and is able to tune the controller to a typical servo system.

Assessment criteria, excellent (5)

The student has an excellent command of the basics of control and servo technology. The student is able to dimension a challenging servo system and select components for it independently. The student is able to utilize modeling and simulation software in a variety of ways in the analysis of servo systems and is able to tune the controller to a typical servo system. The student is able to apply their skills in machine automation motion control systems.

Further information

Literature:
Jari Savolainen, Reijo Vaittinen: Säätötekniikan perusteita

Enrolment period

02.07.2024 - 01.09.2024

Timing

01.09.2024 - 22.12.2024

Credits

5 op

Mode of delivery

Contact teaching

Unit

Mechanical Engineering

Campus

TAMK Main Campus

Teaching languages
  • Finnish
Degree programmes
  • Degree Programme in Mechanical Engineering
Teachers
  • Ville Jouppila
  • Mikko Korpela
Person in charge

Ville Jouppila

Groups
  • 21I190

Objectives (course unit)

The student understands the significance of sustainable development when designing servo systems for machine automation applications.
The student understands the importance of cost-effectiveness, quality and safety when designing motion control applications.
The student is able to dimension and select the components for typical machine automation servo systems.
The student masters the basics of control engineering.
The student is able to exploit a modeling and simulation software for designing and analyzing a servo system.
The student is capable of designing a basic control structure for a servo system.

Content (course unit)

In the course, the structure and different implementation approaches of servo systems for motion control systems are studied.

The mathematical modeling of dynamic systems based on differential equations are studied as well as the modeling in the frequency domain obtained by Laplace transformation.

The basic of control engineering, analysis methods of dynamic systems and basic controller structures of servo systems are considered.

The course includes a project task which involves dimensioning, modeling, simulation and control design of a servo system with a CAD-software.

Further information (course unit)

Literature:
Jari Savolainen, Reijo Vaittinen: Säätötekniikan perusteita

Assessment criteria, satisfactory (1-2) (course unit)

The student adequately masters the basics of control and servo technology. The student is able to dimension a simple servo system and select components for it, assisted if necessary. The student is able to utilize modeling and simulation software assisted in the analysis of servo systems. Can tune the controller to a simple system.

Assessment criteria, good (3-4) (course unit)

The student masters the basics of control and servo technology well. The student is able to dimension a simple servo system and select components for it independently. The student is able to utilize modeling and simulation software in the analysis of servo systems and is able to tune the controller to a typical servo system.

Assessment criteria, excellent (5) (course unit)

The student has an excellent command of the basics of control and servo technology. The student is able to dimension a challenging servo system and select components for it independently. The student is able to utilize modeling and simulation software in a variety of ways in the analysis of servo systems and is able to tune the controller to a typical servo system. The student is able to apply their skills in machine automation motion control systems.

Exam schedules

Agreed during the course.

Assessment methods and criteria

Exam 50%, Laboratory and assignment work 50%

Assessment scale

0-5

Teaching methods

Theory lessons and laboratory work in contact teaching.

Learning materials

The given course material.

Student workload

Contact learning (theory, laboratory) 55h, self learning 70h

Assessment criteria - fail (0) (Not in use, Look at the Assessment criteria above)

The student is not able to complete the exam and laboratory assignments at the demanded level.

Assessment criteria - satisfactory (1-2) (Not in use, Look at the Assessment criteria above)

The student adequately masters the basics of control and servo technology. The student is able to dimension a simple servo system and select components for it, assisted if necessary. The student is able to utilize modeling and simulation software as assisted in the analysis of servo systems. Can tune the controller to a simple system.

Assessment criteria - good (3-4) (Not in use, Look at the Assessment criteria above)

The student masters the basics of control and servo technology well. The student is able to dimension a simple servo system and select components for it independently. The student is able to utilize modeling and simulation software in the analysis of servo systems and is able to tune the controller to a typical servo system.

Assessment criteria - excellent (5) (Not in use, Look at the Assessment criteria above)

The student has an excellent command of the basics of control and servo technology. The student is able to dimension a challenging servo system and select components for it independently. The student is able to utilize modeling and simulation software in a variety of ways in the analysis of servo systems and is able to tune the controller to a typical servo system. The student is able to apply their skills in machine automation motion control systems.

Enrolment period

02.07.2023 - 28.08.2023

Timing

28.08.2023 - 17.12.2023

Credits

5 op

Mode of delivery

Contact teaching

Unit

Mechanical Engineering

Campus

TAMK Main Campus

Teaching languages
  • Finnish
Degree programmes
  • Degree Programme in Mechanical Engineering
Teachers
  • Ville Jouppila
  • Mikko Korpela
Person in charge

Ville Jouppila

Groups
  • 20I190

Objectives (course unit)

The student understands the significance of sustainable development when designing servo systems for machine automation applications.
The student understands the importance of cost-effectiveness, quality and safety when designing motion control applications.
The student is able to dimension and select the components for typical machine automation servo systems.
The student masters the basics of control engineering.
The student is able to exploit a modeling and simulation software for designing and analyzing a servo system.
The student is capable of designing a basic control structure for a servo system.

Content (course unit)

In the course, the structure and different implementation approaches of servo systems for motion control systems are studied.

The mathematical modeling of dynamic systems based on differential equations are studied as well as the modeling in the frequency domain obtained by Laplace transformation.

The basic of control engineering, analysis methods of dynamic systems and basic controller structures of servo systems are considered.

The course includes a project task which involves dimensioning, modeling, simulation and control design of a servo system with a CAD-software.

Further information (course unit)

Literature:
Jari Savolainen, Reijo Vaittinen: Säätötekniikan perusteita

Assessment criteria, satisfactory (1-2) (course unit)

The student adequately masters the basics of control and servo technology. The student is able to dimension a simple servo system and select components for it, assisted if necessary. The student is able to utilize modeling and simulation software assisted in the analysis of servo systems. Can tune the controller to a simple system.

Assessment criteria, good (3-4) (course unit)

The student masters the basics of control and servo technology well. The student is able to dimension a simple servo system and select components for it independently. The student is able to utilize modeling and simulation software in the analysis of servo systems and is able to tune the controller to a typical servo system.

Assessment criteria, excellent (5) (course unit)

The student has an excellent command of the basics of control and servo technology. The student is able to dimension a challenging servo system and select components for it independently. The student is able to utilize modeling and simulation software in a variety of ways in the analysis of servo systems and is able to tune the controller to a typical servo system. The student is able to apply their skills in machine automation motion control systems.

Exam schedules

Agreed during the course.

Assessment methods and criteria

Exam 50%, Laboratory and assignment work 50%

Assessment scale

0-5

Teaching methods

Theory lessons and laboratory work in contact teaching.

Learning materials

The given course material.

Student workload

Contact learning (theory, laboratory) 55h, self learning 70h

Assessment criteria - fail (0) (Not in use, Look at the Assessment criteria above)

The student is not able to complete the exam and laboratory assignments at the demanded level.

Assessment criteria - satisfactory (1-2) (Not in use, Look at the Assessment criteria above)

The student adequately masters the basics of control and servo technology. The student is able to dimension a simple servo system and select components for it, assisted if necessary. The student is able to utilize modeling and simulation software as assisted in the analysis of servo systems. Can tune the controller to a simple system.

Assessment criteria - good (3-4) (Not in use, Look at the Assessment criteria above)

The student masters the basics of control and servo technology well. The student is able to dimension a simple servo system and select components for it independently. The student is able to utilize modeling and simulation software in the analysis of servo systems and is able to tune the controller to a typical servo system.

Assessment criteria - excellent (5) (Not in use, Look at the Assessment criteria above)

The student has an excellent command of the basics of control and servo technology. The student is able to dimension a challenging servo system and select components for it independently. The student is able to utilize modeling and simulation software in a variety of ways in the analysis of servo systems and is able to tune the controller to a typical servo system. The student is able to apply their skills in machine automation motion control systems.

Enrolment period

02.07.2022 - 29.08.2022

Timing

29.08.2022 - 23.12.2022

Credits

5 op

Mode of delivery

Contact teaching

Unit

Mechanical Engineering

Campus

TAMK Main Campus

Teaching languages
  • Finnish
Degree programmes
  • Degree Programme in Mechanical Engineering
Teachers
  • Ville Jouppila
  • Mikko Korpela
Person in charge

Ville Jouppila

Groups
  • 19I190

Objectives (course unit)

The student understands the significance of sustainable development when designing servo systems for machine automation applications.
The student understands the importance of cost-effectiveness, quality and safety when designing motion control applications.
The student is able to dimension and select the components for typical machine automation servo systems.
The student masters the basics of control engineering.
The student is able to exploit a modeling and simulation software for designing and analyzing a servo system.
The student is capable of designing a basic control structure for a servo system.

Content (course unit)

In the course, the structure and different implementation approaches of servo systems for motion control systems are studied.

The mathematical modeling of dynamic systems based on differential equations are studied as well as the modeling in the frequency domain obtained by Laplace transformation.

The basic of control engineering, analysis methods of dynamic systems and basic controller structures of servo systems are considered.

The course includes a project task which involves dimensioning, modeling, simulation and control design of a servo system with a CAD-software.

Further information (course unit)

Literature:
Jari Savolainen, Reijo Vaittinen: Säätötekniikan perusteita

Assessment criteria, satisfactory (1-2) (course unit)

The student adequately masters the basics of control and servo technology. The student is able to dimension a simple servo system and select components for it, assisted if necessary. The student is able to utilize modeling and simulation software assisted in the analysis of servo systems. Can tune the controller to a simple system.

Assessment criteria, good (3-4) (course unit)

The student masters the basics of control and servo technology well. The student is able to dimension a simple servo system and select components for it independently. The student is able to utilize modeling and simulation software in the analysis of servo systems and is able to tune the controller to a typical servo system.

Assessment criteria, excellent (5) (course unit)

The student has an excellent command of the basics of control and servo technology. The student is able to dimension a challenging servo system and select components for it independently. The student is able to utilize modeling and simulation software in a variety of ways in the analysis of servo systems and is able to tune the controller to a typical servo system. The student is able to apply their skills in machine automation motion control systems.

Assessment scale

0-5