Course Information

Course Information
Course Title Code Language Type Semester L+U Hour Credits ECTS
Electronics II EEM373 Turkish Compulsory 5. Semester 4 + 0 4.0 4.0
Prerequisite Courses
Course Level Undergraduate
Mode of delivery
Course Coordinator Doç. Dr. Uğur HASIRCI
Instructor(s) Doç. Dr. Uğur HASIRCI (Güz)
Goals Providing information about using semiconductors components such as BJT, MOSFET, JFET in electronic circuits, power amplifiers, Teoric studies on OpAMP applications.
Course Content
Learning Outcomes
# Öğrenme Kazanımı
0 After completing the course, the students should be able to: 1.Learning and using the structure of basic amplifier circuits. 2.Analyzing, designing and using the differences amplifier that made of FET, BJT. 3.Developing designs for the feedback amplifiers. 4.An ability to identify, formulate, and solve engineering problems. 5.An ability to design and conduct experiments, as well as to analyse data 6.An ability to design and develop the oscillator circuits
0 After completing the course, the students should be able to: 1.Learning and using the structure of basic amplifier circuits. 2.Analyzing, designing and using the differences amplifier that made of FET, BJT. 3.Developing designs for the feedback amplifiers. 4.An ability to identify, formulate, and solve engineering problems. 5.An ability to design and conduct experiments, as well as to analyse data 6.An ability to design and develop the oscillator circuits
Lesson Plan (Weekly Topics)
Week Topics/Applications Method
1. Week FET DC Analysis Presentation (Preparation) Interview Class Hours
1. Week Amplifier design using constant current sources.
2. Week Frequency properties of amplifier circuits. Upper and lower cut off frequencies
2. Week FET DC Analysis Presentation (Preparation) Interview Class Hours
3. Week FET DC Analysis Class Hours Interview Presentation (Preparation)
3. Week Multi stage amplifiers. Calculation of maximum gain without clipping.
4. Week Differential amplifiers using BJT. Design and analyses. Small signal AC properties. Large signal AC analysis. Common mode and differential mode gain.
4. Week FET AC Analysis Class Hours Interview Presentation (Preparation)
5. Week Op-Amp Basics Presentation (Preparation) Interview Class Hours
5. Week Differential amplifiers using BJT. Design and analyses. Small signal AC properties. Large signal AC analysis. Common mode and differential mode gain.
6. Week Differential amplifiers using FET’s. Design and analyses. Small signal AC properties. Large signal AC analyses. Common mode and differential mode gain
6. Week Op-Amp Applications Presentation (Preparation) Interview Class Hours
7. Week Integrated Circuits Presentation (Preparation) Class Hours Interview
7. Week Differential amplifiers using BJT. Design and analyses. Small signal AC properties. Large signal AC analysis. Common mode and differential mode gain.
8. Week Midterm exam
8. Week Midterm exam
9. Week Integrated Circuits Class Hours Interview Presentation (Preparation)
9. Week Current/voltage sampling/comparison circuits and properties.
10. Week Analyses of feedback circuits.
10. Week Oscillators Class Hours Presentation (Preparation) Interview
11. Week Oscillators Presentation (Preparation) Interview Class Hours
11. Week Positive feedback circuits. Oscillator circuits.
12. Week Power amplifiers. A, B, C, D class amplifiers. Calculation of power efficiency.
12. Week Power amplifiers Presentation (Preparation) Interview Class Hours
13. Week Power Sources Class Hours Presentation (Preparation) Interview
13. Week Power amplifiers. A, B, C, D class amplifiers. Calculation of power efficiency.
14. Week Power supply circuits. Regulator circuits with transistors.
14. Week Revisiting the basics Presentation (Preparation) Interview Class Hours
*Midterm and final exam dates are not specified in the 14-week course operation plan. Midterm and final exam dates are held on the dates specified in the academic calendar with the decision of the University Senate.
The Matrix for Course & Program Learning Outcomes
No Program Requirements Level of Contribution
1 2 3 4 5
1 Adequate knowledge in mathematics, science, and related engineering disciplines; ability to use theoretical and applied information in these areas to solve complex engineering problems.
4 Ability to select and use modern techniques and tools necessary for the analysis and solution of complex problems encountered in engineering practice; ability to use information technologies effectively.
6 Ability to work effectively in disciplinary and multidisciplinary teams; ability to work individually.
Relations with Education Attainment Program Course Competencies
Program Requirements DK1
PY1 3
PY4 3
PY6 2
Recommended Sources
Ders Kitabı veya Notu Ders Kitabı veya Ders Notu bulunmamaktadır.
Diğer Kaynaklar
  • R. Boylestad, Louis Nashelsky, Electronic Devices and Circuits, Prentice Hall; 10th edition
  • R. Boylestad, Louis Nashelsky, Electronic Devices and Circuits, Prentice Hall; 10th edition
ECTS credits and course workload
ECTS credits and course workload Quantity Duration (Hour) Total Workload (Hour)
Sınavlar
Midterm 1 1 15 15
Homework 1 2 10 20
Homework 2 2 10 20
Final 1 20 20
Classroom Activities 1 27 27
Total Workload 102
*AKTS = (Total Workload) / 25,5 ECTS Credit of the Course 4.0