| 1. Course Title | Engineering software tools | |||||||
| 2. Code | 4ФЕИТ02Л013 | |||||||
| 3. Study program | ЕАОИЕ | |||||||
| 4. Organizer of the study program (unit, institute, department) | Faculty of Electrical Engineering and Information Technologies | |||||||
| 5. Degree (first, second, third cycle) | First cycle | |||||||
| 6. Academic year/semester | II/4 | 7. Number of ECTS credits | 6 | |||||
| 8. Lecturer | D-r Maja Celeska | |||||||
| 9. Course Prerequisites | Passed: Fundamentals of electrical engineering, Fundamentals of electric circuits | |||||||
| 10. Course Goals (acquired competencies): Ability to independently solve practical problems of design and analysis using application programs. | ||||||||
| 11. Course Syllabus: Principles and methods for solving engineering problems with the help of personal computers. Two-dimensional drawing and three-dimensional modeling Numerical methods for solving electromagnetic and thermal fields. Basics of the finite element method. Procedure for solving problems with MKE. Modern software tools. FEMM – software package. Modeling, simulation and analysis of dynamic systems. Simulink Library. Work with blocks, signals and data. Procedure for making simulation models. Work with the SimPowerSystem library of practical simulations. Basics of technical drawing in AutoCAD. | ||||||||
| 12. Learning methods: Interactive lectures numerical and laboratory exercises, projects, homework. | ||||||||
| 13. Total number of course hours | 3 + 0 + 2 + 0 | |||||||
| 14. Distribution of course hours | 180 | |||||||
| 15. Forms of teaching | 15.1. Lectures-theoretical teaching | 45 | ||||||
| 15.2. Exercises (laboratory, practice classes), seminars, teamwork | 30 | |||||||
| 16. Other course activities | 16.1. Projects, seminar papers | 20 | ||||||
| 16.2. Individual tasks | 40 | |||||||
| 16.3. Homework and self-learning | 45 | |||||||
| 17. Grading | 17.1. Exams | 20 | ||||||
| 17.2. Seminar work/project (presentation: written and oral) | 40 | |||||||
| 17.3. Activity and participation | 0 | |||||||
| 17.4. Final exam | 40 | |||||||
| Grading criteria (points) | up to 50 points | 5 (five) (F) | ||||||
| from 51to 60 points | 6 (six) (E) | |||||||
| from 61to 70 points | 7 (seven) (D) | |||||||
| from 71to 80 points | 8 (eight) (C) | |||||||
| from 81to 90 points | 9 (nine) (B) | |||||||
| from 91to 100 points | 10 (ten) (A) | |||||||
| 19. Conditions for acquiring teacher’s signature and for taking final exam | Realized activities 15.1 and 15.2 | |||||||
| 20. Forms of assessment | During the semester, the student has to prepare and present two project assignments, as well as to fulfill all laboratory exercises in order to gain the right to take the exam. At the same time, the written examination is realized either through two partial exams (120 min each) during the semester or through a final written exam (120 min) – at the end of the semester. The student who has successfully completed the previous activities, is required to pass the final oral exam (60 min). The grade is formed by appropriate scoring of all the above activities. | |||||||
| 21. Language | Macedonian and English | |||||||
| 22. Method of monitoring of teaching quality | Internal evaluation and surveys | |||||||
| 23. Literature | ||||||||
| 23.1. Required Literature | ||||||||
| No. | Author | Title | Publisher | Year | ||||
| 1 | К. Најденкоски | ИСА-Интерна скрипта | ФЕИТ | 2012 | ||||
| 2 | David Meeker | Finite Element Method Version 4.2 | 2018 | |||||
| 3 | Randy H. Shih | AutoCAD 2012 Tutorial – First Level: 2D Fundamentals | SDC Publications | 2011 | ||||
| 23.1. Required Literature | ||||||||
| No. | Author | Title | Publisher | Year | ||||
| 23.2. Additional Literature | ||||||||
| No. | Author | Title | Publisher | Year | ||||
| 1 | Viktor Perelmuter | Renewable Energy Systems: Simulation with Simulink® and SimPowerSystems | CRC Press | 2016 | ||||
