Education Information System

Course Title	Code	Semester	L+U Hour	Credits	ECTS
Dc Circuit Analysis	MEK2109	2. Semester	2 + 1	3.0	3.0

Prerequisites

None

Language of Instruction	Turkish
Course Level	Associate
Course Type
Mode of delivery	Face to face
Course Coordinator	Assist. Prof. Dr. Oğuzhan KENDİRLİ
Instructor(s)	Oğuzhan KENDİRLİ
Assistants
Goals	Understanding the basic concepts of electrical circuits, aimed to learn the correct circuit in steady state solution methods.
Course Content	Fundamentals of Electric Current, Direct Current Circuit Solutions, Kirchhoff’s Laws, Welding Links, Direct Current Capacitor and Inductor, Energy and Power Computing, Environmental Flows Method, Node Voltage Method, Superposition Theorem, Norton's Theorem, Maximum Power Transfer Theorem
Learning Outcomes	- To understand the basic laws of electrical circuits - Grasp circuit analysis methods - To solve the DC circuit - Circuits to analyze the solutions - To take advantage of the computer program in the circuit solution

Week	Topics	Learning Methods
1. Week	Electrical quantities and defining the basic concepts of ge, current, voltage, resistance and conductivity, and temperature dependence of the resistance to physical size.
2. Week	Identification of electrical quantities voltage current resistance relationships (Ohms law), electric circuit, elektromotorkuvvet (emf), electricity (business) and electrical power
3. Week	Basic electrical circuit variables active and passive components, voltage sources, current sources, dependent sources
4. Week	Resistors connected in series circuits and Kirchoff s voltage law, sample problems
5. Week	Parallel resistor circuits and Kirchoff s current law, Serial parallel (mixed) resistive circuits, sample problems
6. Week	The methods used in solving electrical circuit loop current method, two surround electrical circuits, three peripheral electrical circuits, sample problems
7. Week	Method of methods used in solving electrical circuit node voltages
8. Week	Midterm
9. Week	The fundamental theorem used in the solution of electrical circuits superposition theorem, sample circuit solutions.
10. Week	The fundamental theorem used in the solution of electrical circuits Thevenins theorem, sample circuit solutions.
11. Week	Nortons theorem and Nortons theorem with circuit solutions used in the solution of electrical circuits
12. Week	Maximum power theory used in the solution of electrical circuits, star / delta and three star transformation method, sample circuit solutions relevant
13. Week	Capacitor circuit in direct current, the capacity of the capacitor, the time constant of the DC circuit capacitor, the stored energy, the capacitor connections
14. Week	Coil circuit in direct current, inductance coil, the coil DC circuit time constant, the stored energy, coil connections

Yağımlı, M. & Akar, F. (2002) Doğru Akım Devreleri & Problem Çözümleri

Direct Current (DC) Circuit Analysis Seçkin Publishing

Document

Devre Analizi Tüm Dönem

Program Requirements	Contribution Level	DK1	DK2	DK3	DK4	DK5	Measurement Method
PY2	4	0	0	0	0	0	-
PY3	4	0	0	0	0	0	-
PY4	4	0	0	0	0	0	-
PY5	3	0	0	0	0	0	-
PY6	3	0	0	0	0	0	-
PY7	2	0	0	0	0	0	-
PY8	3	0	0	0	0	0	-
PY9	4	0	0	0	0	0	-
PY12	3	0	0	0	0	0	-
PY14	4	0	0	0	0	0	-

*DK = Course's Contrubution.

	0	1	2	3	4	5
Course's Level of contribution	None	Very Low	Low	Fair	High	Very High
Method of assessment/evaluation		Written exam	Oral Exams	Assignment/Project	Laboratory work	Presentation/Seminar

Event	Quantity	Duration (Hour)	Total Workload (Hour)
Course Hours	14	3	42
Preparation, After Class Study	2	7	14
Other Activities	1	0.5	0.5
Midterm 1	1	10	10
Final	1	10	10
Total Workload			76.5
ECTS Credit of the Course			25.5 3.0