Course detail
Computer Science in High Power Engineering
FEKT-BISEAcad. year: 2010/2011
The course is approached to demonstration of computer science using in the field of electrical machines, apparatus, drives and power electronics.
Language of instruction
Czech
Number of ECTS credits
2
Mode of study
Not applicable.
Guarantor
Learning outcomes of the course unit
Students will get information about selected high-tech software packages, which are used in the field of high power engineering. Possibilities of computer aided solutions of typical high power engineering problems will be presented.
Prerequisites
The subject knowledge on the secondary school level is required.
Co-requisites
Not applicable.
Planned learning activities and teaching methods
Teaching methods depend on the type of course unit as specified in the article 7 of BUT Rules for Studies and Examinations.
Assesment methods and criteria linked to learning outcomes
4 written tests (max 24 pts), attendance (max 12 pts). Required minimum of 26 pts.
Course curriculum
1. Guidelines of faculty computational network.
2. Solution of high power electrical engineering tasks using a method of finite elements (ANSYS).
3. Basics of data acquisition, analysis and presentation (LabVIEW).
4. Computational modeling in high power engineering (AutoCAD, Inventor).
5. Computational visualization and animation in high power engineering (3ds MAX).
6. Analysis of object functions and contradictions - creation of inventive tasks (TRIZ).
7. Solution of inventive tasks (TRIZ).
8. Principles of selected problems solution using MATLAB SIMULINK - introduction, basic mathematical operations, function graphs - part 1.
9. Principles of selected problems solution using MATLAB SIMULINK - introduction, basic mathematical operations, function graphs - part 2.
10. Principles of selected problems solution using MATLAB SIMULINK - introduction to dynamic systems simulations.
11. Principles of selected problems solution using MATLAB SIMULINK - model of pedant and torsional pendulum - part 1.
12. Principles of selected problems solution using MATLAB SIMULINK - model of pedant and torsional pendulum - part 2.
13. Principles of selected problems solution using MATLAB SIMULINK - simulation of non-continuous systems.
2. Solution of high power electrical engineering tasks using a method of finite elements (ANSYS).
3. Basics of data acquisition, analysis and presentation (LabVIEW).
4. Computational modeling in high power engineering (AutoCAD, Inventor).
5. Computational visualization and animation in high power engineering (3ds MAX).
6. Analysis of object functions and contradictions - creation of inventive tasks (TRIZ).
7. Solution of inventive tasks (TRIZ).
8. Principles of selected problems solution using MATLAB SIMULINK - introduction, basic mathematical operations, function graphs - part 1.
9. Principles of selected problems solution using MATLAB SIMULINK - introduction, basic mathematical operations, function graphs - part 2.
10. Principles of selected problems solution using MATLAB SIMULINK - introduction to dynamic systems simulations.
11. Principles of selected problems solution using MATLAB SIMULINK - model of pedant and torsional pendulum - part 1.
12. Principles of selected problems solution using MATLAB SIMULINK - model of pedant and torsional pendulum - part 2.
13. Principles of selected problems solution using MATLAB SIMULINK - simulation of non-continuous systems.
Work placements
Not applicable.
Aims
To get information about selected software packages, which are used in high power engineering. To demonstrate possibilities of these packages and to recommend ways of their using in solution of common problems in high power engineering practice.
Specification of controlled education, way of implementation and compensation for absences
The content and forms of instruction in the evaluated course are specified by a regulation issued by the lecturer responsible for the course and updated for every academic year.
Recommended optional programme components
Not applicable.
Prerequisites and corequisites
Not applicable.
Basic literature
Aubrecht V.: Infomatika v silnoproudé elektrotechnice
Recommended reading
Not applicable.
Classification of course in study plans
Type of course unit
Exercise in computer lab
26 hod., compulsory
Teacher / Lecturer
Syllabus
1. Guidelines of faculty computational network.
2. Solution of high power electrical engineering tasks using a method of finite elements (ANSYS).
3. Basics of data acquisition, analysis and presentation (LabVIEW).
4. Computational modeling in high power engineering (AutoCAD, Inventor).
5. Computational visualization and animation in high power engineering (3ds MAX).
6. Analysis of object functions and contradictions - creation of inventive tasks (TRIZ).
7. Solution of inventive tasks (TRIZ).
8. Principles of selected problems solution using MATLAB SIMULINK - introduction, basic mathematical operations, function graphs - part 1.
9. Principles of selected problems solution using MATLAB SIMULINK - introduction, basic mathematical operations, function graphs - part 2.
10. Principles of selected problems solution using MATLAB SIMULINK - introduction to dynamic systems simulations.
11. Principles of selected problems solution using MATLAB SIMULINK - model of pedant and torsional pendulum - part 1.
12. Principles of selected problems solution using MATLAB SIMULINK - model of pedant and torsional pendulum - part 2.
13. Principles of selected problems solution using MATLAB SIMULINK - simulation of non-continuous systems.
2. Solution of high power electrical engineering tasks using a method of finite elements (ANSYS).
3. Basics of data acquisition, analysis and presentation (LabVIEW).
4. Computational modeling in high power engineering (AutoCAD, Inventor).
5. Computational visualization and animation in high power engineering (3ds MAX).
6. Analysis of object functions and contradictions - creation of inventive tasks (TRIZ).
7. Solution of inventive tasks (TRIZ).
8. Principles of selected problems solution using MATLAB SIMULINK - introduction, basic mathematical operations, function graphs - part 1.
9. Principles of selected problems solution using MATLAB SIMULINK - introduction, basic mathematical operations, function graphs - part 2.
10. Principles of selected problems solution using MATLAB SIMULINK - introduction to dynamic systems simulations.
11. Principles of selected problems solution using MATLAB SIMULINK - model of pedant and torsional pendulum - part 1.
12. Principles of selected problems solution using MATLAB SIMULINK - model of pedant and torsional pendulum - part 2.
13. Principles of selected problems solution using MATLAB SIMULINK - simulation of non-continuous systems.