| ELECTRICAL AND ELECTRONICS ENGINEERING | |||||
| Bachelor | TR-NQF-HE: Level 6 | QF-EHEA: First Cycle | EQF-LLL: Level 6 | ||
| Course Code | Course Name | Semester | Theoretical | Practical | Credit | ECTS |
| EEE2102 | Circuit Theory II | Spring | 3 | 0 | 3 | 6 |
| The course opens with the approval of the Department at the beginning of each semester |
| Language of instruction: | En |
| Type of course: | Must Course |
| Course Level: | Bachelor |
| Mode of Delivery: | Face to face |
| Course Coordinator : | Dr. Öğr. Üyesi CAVİT FATİH KÜÇÜKTEZCAN |
| Course Lecturer(s): |
Dr. Öğr. Üyesi MUSTAFA EREN YILDIRIM |
| Course Objectives: | This course introduces circuits energized by time-varying voltage or current sources and mathematical principles for analyzing such circuits. The course also introduces special circuits such as balanced three-phase circuits and frequency selective circuits. After completing the course, students will be able to develop appropriate modeling equations for designing and solving electric circuits. |
|
The students who have succeeded in this course; 1. Solve for the sinusoidal steady-state response of a circuit with time-varying sources 2. Analyze a circuit by phasor diagrams 3. Analyze circuits with tranformers 4. Calculate the rms value, instantaneous, average, reactive, and complex power 5. Calculate the impedance for maximum power transfer 6. Analyze balanced three-phase circuits 7. Solve an electric circuit by Laplace transform 8. Design frequency selective circuits such as low-pass, high-pass and bandpass filters |
| 1. Sinusoidal steady state analysis, frequency domain and phasor transformation 2. Circuit analysis in frequency domain, passive circuit elements, Kirchhoff's laws, series, parallel and delta-Y simplifications, source transformations, Thevenin Norton equivalent, node voltage method, mesh current method, phasor diagrams 3. Transformer and ideal transformer 4. Sinusoidal steady state power calculations, instantaneous power, average and reactive power, the rms value and power calculations, complex power, maximum power transfer 5. Balanced three phase circuits, three phase voltage sources, analysis of Y-Y circuit, analysis of Y-delta circuit, delta-Y conversion for the source, power calculations in balanced three phase circuits, measuring average power in three phase circuits 6. Laplace transform, step function, impulse function, functional and operational transforms, applying the Laplace transform, inverse transforms, poles and zeros of Laplace transform, initial and final value theorems 7. The Laplace transform in circuit analysis, circuit elements and circuit analysis in s domain, applications, transfer function, partial fraction expansion, convolution integral, steady-state sinusoidal response, impulse function in circuit analysis 8. Frequency selective circuits, low-pass filters, high-pass filters, bandpass filters, bandreject filters |
| Week | Subject | Related Preparation | |
| 1) | Sinusoidal steady state analysis, sinusoidal source, sinusoidal response, phasor, passive circuit elements in the frequency domain | Review complex numbers, read sections 9.1 to 9.4 of Electric Circuits by Nilsson and Riedel. | |
| 2) | Kirchhoff's laws, series, parallel and delta-Y simplifications, source transformations, Thevenin Norton equivalent, node voltage method in the frequency domain | Read sections 9.5 to 9.8 of Electric Circuits by Nilsson and Riedel. | |
| 3) | Mesh current method in frequency domain, transformer, ideal transformer, phasor diagrams, practical perspective: a household distribution | Read sections 9.9 to 9.12 of Electric Circuits by Nilsson and Riedel | |
| 4) | Sinusoidal steady state power calculations, instantaneous power, average and reactive power, the rms value and power calculations | Read sections 10.1 to 10.3 of Electric Circuits by Nilsson and Riedel | |
| 5) | Complex power, power calculations, maximum power transfer, practical perspective: heating appliances | Read sections 10.4 to 10.6 of Electric Circuits by Nilsson and Riedel | |
| 6) | Balanced three phase circuits, three phase voltage sources, analysis of Y-Y circuit | Read sections 11.1 to 11.3 of Electric Circuits by Nilsson and Riedel | |
| 7) | Analysis of Y-delta circuit, delta-Y conversion for the source, power calculations in balanced three phase circuits, measuring average power in three phase circuits, practical perspective: transmission and distribution of electric power | Read sections 11.4 to 11.6 of Electric Circuits by Nilsson and Riedel | |
| 8) | Laplace transform, step function, impulse function, functional and operational transforms | Read sections 12.1 to 12.5 of Electric Circuits by Nilsson and Riedel | |
| 9) | Applying the Laplace transform, inverse transforms, poles and zeros of Laplace transform, initial and final value theorems, practical perspective: transient effects | Read sections 12.6 to 12.9 of Electric Circuits by Nilsson and Riedel | |
| 10) | The Laplace transform in circuit analysis, circuit elements and circuit analysis in s domain, applications | Read sections 13.1 to 13.3 of Electric Circuits by Nilsson and Riedel | |
| 11) | Transfer function, partial fraction expansion, convolution integral | Read sections 13.4 to 13.6 of Electric Circuits by Nilsson and Riedel | |
| 12) | Steady-state sinusoidal response, impulse function in circuit analysis, practical perspective: surge suppressors | Read sections 13.7 to 13.8 of Electric Circuits by Nilsson and Riedel | |
| 13) | Frequency selective circuits, low-pass filters, high-pass filters | Read sections 14.1 to 14.3 of Electric Circuits by Nilsson and Riedel | |
| 14) | Bandpass filters, bandreject filters, practical perspective: pushbutton telephone circuits | Read sections 14.4 to 14.5 of Electric Circuits by Nilsson and Riedel | |
| Course Notes: | Electric Circuits, James W. Nilsson and Susan A. Riedel, Prentice Hall, 9th Edition, Prentice Hall. |
| References: | Introduction to Circuit Analysis, Robert L. Boylestad, 12th Edition, Prentice Hall. Fundamentals of Electric Circuits, Charles Alexander and Matthew Sadiku, 5h Edition, McGraw-Hill. Linear and Nonlinear Circuits, Leon O. Cuha, Charles A. Desoer and Ernest S. Kuh, McGraw-Hill. Introduction to Circuit Analysis and Design, Michael D. Ciletti, Oxford University Press Inc. Introduction to Electric Circuits, Richard C. Dorf and James A. Svoboda, 8th Edition, Wiley. Circuit Theory, U. A. Bakshi and A. V. Bakshi, 1st edition, Technical Publications. |
| Semester Requirements | Number of Activities | Level of Contribution |
| Attendance | 0 | % 0 |
| Laboratory | 0 | % 0 |
| Application | 0 | % 0 |
| Field Work | 0 | % 0 |
| Special Course Internship (Work Placement) | 0 | % 0 |
| Quizzes | 0 | % 0 |
| Homework Assignments | 0 | % 0 |
| Presentation | 0 | % 0 |
| Project | 0 | % 0 |
| Seminar | 0 | % 0 |
| Midterms | 1 | % 40 |
| Preliminary Jury | 0 | % 0 |
| Final | 1 | % 60 |
| Paper Submission | 0 | % 0 |
| Jury | 0 | % 0 |
| Bütünleme | % 0 | |
| Total | % 100 | |
| PERCENTAGE OF SEMESTER WORK | % 40 | |
| PERCENTAGE OF FINAL WORK | % 60 | |
| Total | % 100 | |
| Activities | Number of Activities | Duration (Hours) | Workload |
| Course Hours | 14 | 3 | 42 |
| Laboratory | 0 | 0 | 0 |
| Application | 0 | 0 | 0 |
| Special Course Internship (Work Placement) | 0 | 0 | 0 |
| Field Work | 0 | 0 | 0 |
| Study Hours Out of Class | 16 | 9 | 144 |
| Presentations / Seminar | 0 | 0 | 0 |
| Project | 0 | 0 | 0 |
| Homework Assignments | 0 | 0 | 0 |
| Quizzes | 0 | 0 | 0 |
| Preliminary Jury | 0 | 0 | 0 |
| Midterms | 1 | 2 | 2 |
| Paper Submission | 0 | 0 | 0 |
| Jury | 0 | 0 | 0 |
| Final | 1 | 2 | 2 |
| Total Workload | 190 | ||
| No Effect | 1 Lowest | 2 Low | 3 Average | 4 High | 5 Highest |
| Program Outcomes | Level of Contribution | |
| 1) | Adequate knowledge in mathematics, science and electric-electronic engineering subjects; ability to use theoretical and applied information in these areas to model and solve engineering problems. | 5 |
| 2) | Ability to identify, formulate, and solve complex engineering problems; ability to select and apply proper analysis and modeling methods for this purpose. | 5 |
| 3) | Ability to design a complex system, process, device or product under realistic constraints and conditions, in such a way as to meet the desired result; ability to apply modern design methods for this purpose. (Realistic constraints and conditions may include factors such as economic and environmental issues, sustainability, manufacturability, ethics, health, safety issues, and social and political issues, according to the nature of the design.) | 4 |
| 4) | Ability to devise, select, and use modern techniques and tools needed for electrical-electronic engineering practice; ability to employ information technologies effectively. | 5 |
| 5) | Ability to design and conduct experiments, gather data, analyze and interpret results for investigating engineering problems. | 5 |
| 6) | Ability to work efficiently in intra-disciplinary and multi-disciplinary teams; ability to work individually. | 2 |
| 7) | Ability to communicate effectively in English and Turkish (if he/she is a Turkish citizen), both orally and in writing. | 1 |
| 8) | Recognition of the need for lifelong learning; ability to access information, to follow developments in science and technology, and to continue to educate him/herself. | 1 |
| 9) | Awareness of professional and ethical responsibility. | 1 |
| 10) | Information about business life practices such as project management, risk management, and change management; awareness of entrepreneurship, innovation, and sustainable development. | 1 |
| 11) | Knowledge about contemporary issues and the global and societal effects of engineering practices on health, environment, and safety; awareness of the legal consequences of engineering solutions. | 2 |