ASE-3016 Microactuators and Active Actuator Materials, 5 cr
Person responsible
Pasi Kallio
Lessons
Implementation 1: ASE-3016 2015-01
Study type | P1 | P2 | P3 | P4 | Summer |
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Requirements
Accepted laboratory exercises (2) and an accepted project work. Attendance at six or more 2 h lectures. Passed quizes.
Completion parts must belong to the same implementation
Learning Outcomes
After the course, the student is able to - use and implement applications for real-time data acquisition and control using xPC Target environment - name typical displacement sensors and use laser distance sensors - explain piezoelectric effect and the operation principles of typical piezoelectric actuators, use piezoelectric actuators, analyse the properties of piezoelectric actuators, and implement feedback control for piezoelectric actuators - explain shape memory effect and the operation principles of typical shape memory actuators, use shape memory actuators, and analyse their properties using own measurements - explain magnetostrictive effect and the operation principles of magnetostrictive actuators, use magnetostrictive actuators, and analyse their properties using own measurements - recognise different types of electro active polymers and explain their operation principles - explain magnetic shape memory (MSM) effect and the operation principles of MSM actuators - explain the operation principles magnetorheological fluids - report own measurement results in a technical writing style
Content
Content | Core content | Complementary knowledge | Specialist knowledge |
1. | Piezoelectric actuators: effect, design, actuator types, figures of merit. Control aspects of piezoelectric actuators. | Applications of piezoelectric actuators. | Fabrication and material issues of piezoelectric actuators. |
2. | Shape memory actuators: effect, design, actuator types, figures of merit. | Control aspects and applications of shape memory actuators. | Fabrication and material issues of shape memory actuators. |
3. | Electroactive polymer actuators: effect, design, actuator types, figures of merit. | Control aspects and applications of electroactive polymer actuators. | Fabrication and material issues of electroactive polymer actuators. |
4. | Magnetostrictive actuators: effect, design, actuator types, figures of merit. | Control aspects and applications of magnetostrictive actuators. | Fabrication and material issues of magnetostrictive actuators. |
5. | Magnetorheological actuators: effect, design, actuator types, figures of merit. | Control aspects and applications of magnetorheological actuators. | Fabrication and material issues of magnetorheological actuators. |
6. | Matlab's xPC Target as a data acquisition and control platform. |
Instructions for students on how to achieve the learning outcomes
Option 1: The course assessment is based on the written exam. The students can gain bonus points by participating the lectures. The bonus points will be taken into account in the final grade. Option 2: The course assessment is based on the evaluation of the laboratory exercises (4) and the project report. Active attendance at the lectures is required.
Assessment scale:
Numerical evaluation scale (1-5) will be used on the course
Partial passing:
Study material
Type | Name | Author | ISBN | URL | Additional information | Examination material |
Book | Emerging Actuator Technologies: a Micromechatronic Approach | Jose L. Pons | 0-470-09197-5 | Yes |
Prerequisites
Course | Mandatory/Advisable | Description |
ASE-2310 Johdatus mikrosysteemitekniikkaan | Mandatory | 1 |
ASE-2316 Introduction to Microsystem Technology | Mandatory | 1 |
1 . One of the courses is obligatory.
Correspondence of content
Course | Corresponds course | Description |
ASE-3016 Microactuators and Active Actuator Materials, 5 cr | ACI-51306 Microrobotics and Microactuators, 5 cr | |
ASE-3016 Microactuators and Active Actuator Materials, 5 cr | ASE-3016 Microactuators and Active Actuator Materials, 5 cr |