Course Information
SemesterCourse Unit CodeCourse Unit TitleT+P+LCreditNumber of ECTS Credits
1ELE101Electrical Circuits 12+2+036

Course Details
Language of Instruction Turkish
Level of Course Unit Associate Degree
Department / Program Electricity
Mode of Delivery Face to Face
Type of Course Unit Compulsory
Objectives of the Course Explaining the basic concepts of electrical circuits and analyzing the steady-state solution methods of direct current circuits
Course Content Basic concepts related to electricity, basic electrical laws (Ohm's law and Kirchhoff's laws), circuit solution methods (node ??analysis, loop analysis, superposition theorem, Thevenin and Norton theorems)
Course Methods and Techniques Face to face and practical education
Prerequisites and co-requisities None
Course Coordinator Asist Prof.Dr. Tuğçe Sena ALTUNTAŞ tugce.altuntas@gedik.edu.tr
Name of Lecturers Instructor Ceren AYDIN ceren.aydin@gedik.edu.tr
Asist Prof. Tuğçe Sena ALTUNTAŞ tugce.altuntas@gedik.edu.tr
Assistants None
Work Placement(s) No

Recommended or Required Reading
Resources Dr. Zeki Uğurata KOCABIYIKOĞLU, “Temel Elektrik-1”.
James W. Nilsson, Susan A. Riedel, "Elektrik Devreleri"
Charles K. Alexander, Matthew N. O. Sadiku, "Elektrik Devrelerinin Temelleri", Çeviren: Uğur Savaş Selamoğulları
Lecture notes prepared by instructors
Vize sınavı % 40ı, Final sınavı % 60

Course Category
Mathematics and Basic Sciences %50
Engineering %25
Field %25

Planned Learning Activities and Teaching Methods
Activities are given in detail in the section of "Assessment Methods and Criteria" and "Workload Calculation"

Assessment Methods and Criteria
In-Term Studies Quantity Percentage
Mid-terms 1 % 30
Practice 1 % 30
Final examination 1 % 40
Total
3
% 100

 
ECTS Allocated Based on Student Workload
Activities Quantity Duration Total Work Load
Course Duration 14 2 28
Hours for off-the-c.r.stud 14 4 56
Mid-terms 1 14 14
Practice 14 2 28
Final examination 1 28 28
Total Work Load   Number of ECTS Credits 6 154

Course Learning Outcomes: Upon the successful completion of this course, students will be able to:
NoLearning Outcomes
1 To be able to explain the basic concepts of electricity, electrical quantities and units, basic properties and working principles of passive circuit elements (resistor, coil and capacitor)
2 Ability to perform unit conversion of electrical units (from lower floor to upper floor - from upper floor to lower floor)
3 Explain the basic laws of electrical circuits
4 To be able to apply the basic laws of electrical circuits (Ohm's law, Kirchhoff's Current Law and Kirchhoff's Voltage Law) in solving direct current circuits
5 To be able to apply electrical circuit solution theorems (Thevenin Theorem, Norton Theorem, Superposition Theorem) in solving direct current circuits
6 Ability to perform applications related to direct current circuits


Weekly Detailed Course Contents
WeekTopicsStudy MaterialsMaterials
1 Basic concepts related to electricity, electrical quantities and units, unit conversion Lecture notes prepared by instructors
2 Calculation of resistor color codes, electrical circuit concept, Ohm's law, sample problem solutions related to the subject Lecture notes prepared by instructors
3 Active and passive circuit elements, voltage sources, current sources, dependent sources Lecture notes prepared by instructors
4 Series connected resistance circuits and Kirchoff's voltage law, sample problem solutions related to the subject Lecture notes prepared by instructors
5 Parallel connected resistor circuits and Kirchoff's current law, sample problem solutions related to the subject Lecture notes prepared by instructors
6 Series-parallel (mixed) resistance circuits, sample problem solutions related to the subject Lecture notes prepared by instructors
7 Star-delta and delta-star conversion method, sample circuit solutions related to the subject Lecture notes prepared by instructors
8 Midterm
9 Methods used in solving electrical circuits; environmental current method, sample problem solutions related to the subject Lecture notes prepared by instructors
10 Methods used in solving electrical circuits; environmental current method, sample problem solutions related to the subject Lecture notes prepared by instructors
11 Methods used in solving electrical circuits; node voltage method, sample problem solutions related to the subject Lecture notes prepared by instructors
12 Methods used in solving electrical circuits; node voltage method, sample problem solutions related to the subject Lecture notes prepared by instructors
13 Basic theorems used in solving electrical circuits; superposition theorem, sample problem solutions related to the subject Lecture notes prepared by instructors
14 Basic theorems used in solving electrical circuits; Thevenin theorem, sample circuit solutions related to the subject Lecture notes prepared by instructors
15 Norton's theorem used in solving electrical circuits, sample circuit solutions related to the subject Lecture notes prepared by instructors


Contribution of Learning Outcomes to Programme Outcomes
P1 P2 P3 P4 P5 P6 P7 P8 P9 P10 P11 P12 P13
C1 5 3 1 1 2 1 5 1 1 1 1 1 5
C2 5 3 1 1 2 1 5 1 1 1 1 1 5
C3 5 3 1 1 2 1 5 1 2 1 1 1 5
C4 5 3 1 1 2 1 5 1 2 1 1 1 5
C5 5 3 1 1 2 1 5 1 1 1 1 1 5
C6 5 5 4 1 5 1 5 1 5 4 1 1 5

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