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BASICS OF ELECTRICAL ENGINEERING PROGRAMME COURSE DESCRIPTION

Code Name of the Course Unit Semester In-Class Hours (T+P) Credit ECTS Credit
EEE201 BASICS OF ELECTRICAL ENGINEERING 3 4 3 5

GENERAL INFORMATION

Language of Instruction : English
Level of the Course Unit : BACHELOR'S DEGREE, TYY: + 6.Level, EQF-LLL: 6.Level, QF-EHEA: First Cycle
Type of the Course : Compulsory
Mode of Delivery of the Course Unit -
Coordinator of the Course Unit Assist.Prof. OĞUZHAN ÖZTAŞ
Instructor(s) of the Course Unit Assist.Prof. YUSUF GÜRCAN ŞAHİN
Course Prerequisite No

OBJECTIVES AND CONTENTS

Objectives of the Course Unit: The aim of this course is to teach electrical circuit theorems, electronic circuit elements and analysis and synthesis of electronic circuits.
Contents of the Course Unit: Theorems of electrical circuits and electronic circuit elements and circuits.

KEY LEARNING OUTCOMES OF THE COURSE UNIT (On successful completion of this course unit, students/learners will or will be able to)

Apply circuit analysis and synthesis using basic electrical theorems.
Can report and apply the analysis of electronic circuits for low complexity applications.
Realize electronic circuits that can function in real life conditions.

WEEKLY COURSE CONTENTS AND STUDY MATERIALS FOR PRELIMINARY & FURTHER STUDY

Week Preparatory Topics(Subjects) Method
1 - Basic quality parameters related to electricity, Electricity generation, transmission,distribution and consumption chain, -
2 - Duties, Authorities and Responsibilities of Electrical and Electronics Engineers, Working principles and procedures, International standards, regulations -
3 - Basic concepts about electricity, -
4 - Electrical circuit elements, Series, parallel, complex, star-delta bonding,Kirchoff's laws -
5 - Analysis of simple circuits with resistors, mesh current analysis and nodal voltage analysis -
6 - Mesh current analysis and nodal voltage analysis, Circuit Theorems-Linearity feature, Superposition -
7 - Circuit Theorems-Source Transformation, Thevenin and Norton Theorems, Maximum Power Transfer -
8 - MID-TERM EXAM -
9 - Analysis of circuits with operational amplifiers and resistors -
10 - Capacitor and inductor circuit elements, analysis of first order circuits with capacitors or inductors -
11 - Analysis of first order circuits containing capacitors or inductors -
12 - Sinusoidal steady-state analysis, phasor concept -
13 - Transforming the circuits with sinusoidal source to frequency dimension and applying basic circuit analysis methods in frequency dimension -
14 - Thevenin, Norton, Superposition and Maximum Power theorems in a sinusoidal steadystate. -
15 - Thevenin, Norton, Superposition and Maximum Power theorems in a sinusoidal steadystate. -
16 - FINAL EXAM -
17 - FINAL EXAM -

SOURCE MATERIALS & RECOMMENDED READING

Basic Electrical Engineering, by J. J. Cathey, Schaum’s Outlines, McGrawHill, 1983.
Fundamentals of Electrical Engineering, G. Rizzoni, McGraw-Hill, 2009

ASSESSMENT

Assessment & Grading of In-Term Activities Number of Activities Degree of Contribution (%) Description
Level of Contribution
0 1 2 3 4 5

CONTRIBUTION OF THE COURSE UNIT TO THE PROGRAMME LEARNING OUTCOMES

KNOWLEDGE

Theoretical

Programme Learning Outcomes Level of Contribution
0 1 2 3 4 5
1
Explains the fundamental engineering concepts of computer science and relates them to the groundwork of computer science.
4

KNOWLEDGE

Factual

Programme Learning Outcomes Level of Contribution
0 1 2 3 4 5
1
Uses theoretical and practical knowledge coming from mathematics, probability, statistics and various other branches of life sciences, to find solutions to engineering problems.
4

SKILLS

Cognitive

Programme Learning Outcomes Level of Contribution
0 1 2 3 4 5
1
Determines the components and the underlying process of a system and designs an appropriate computational model under reasonable constraints.
3
2
Designs a computer-aided conceptual model with modern techniques.
3

SKILLS

Practical

Programme Learning Outcomes Level of Contribution
0 1 2 3 4 5
1
Determines, detects and analyzes the areas of computer science applications and develops appropriate solutions.
5
2
Identifies, models and solves computer engineering problems by applying appropriate analytical methods.
5
3
Determines and uses the necessary information technologies in an efficient way for engineering applications.
4

OCCUPATIONAL

Autonomy & Responsibility

Programme Learning Outcomes Level of Contribution
0 1 2 3 4 5
1
Possess the responsibility and ability to design and conduct experiments for engineering problems by collecting, analyzing and interpreting data.
5
2
Possess the ability to conduct effective individual study.
5
3
Takes responsibility as a team work and contributes in an effective way.
4

WORKLOAD & ECTS CREDITS OF THE COURSE UNIT

Workload for Learning & Teaching Activities

Type of the Learning Activites Learning Activities (# of week) Duration (hours, h) Workload (h)
Lecture & In-Class Activities 14 2 28
Preliminary & Further Study 14 2 28
Land Surveying 0 0 0
Group Work 0 0 0
Laboratory 0 0 0
Reading 0 0 0
Assignment (Homework) 1 5 5
Project Work 0 0 0
Seminar 0 0 0
Internship 0 0 0
Technical Visit 0 0 0
Web Based Learning 0 0 0
Implementation/Application/Practice 14 2 28
Practice at a workplace 0 0 0
Occupational Activity 0 0 0
Social Activity 0 0 0
Thesis Work 0 0 0
Field Study 0 0 0
Report Writing 5 1 5
Final Exam 1 1 1
Preparation for the Final Exam 1 10 10
Mid-Term Exam 1 1 1
Preparation for the Mid-Term Exam 1 10 10
Short Exam 2 1 2
Preparation for the Short Exam 2 5 10
TOTAL 56 0 128
Total Workload of the Course Unit 128
Workload (h) / 25.5 5
ECTS Credits allocated for the Course Unit 5,0