| Course code |
02 05 6297 00 |
| Number of ECTS points |
5 |
| Course title in the language of instruction |
Electronics and Electrical Engineering (Elektronika i elektrotechnika) |
| Course title in Polish |
Electronics and Electrical Engineering |
| Course title in English |
Electronics and Electrical Engineering (Elektronika i elektrotechnika) |
| Language of instruction |
English |
| Form of classes |
|
Lecture |
Tutorials |
Laboratory |
Project |
Seminar |
Other |
Total of teaching hours during semester |
| Contact hours |
30 |
30 |
20 |
|
|
0 |
80 |
| E-learning |
No |
No |
No |
No |
No |
No |
|
| Assessment criteria (weightage) |
0.50 |
0.30 |
0.20 |
|
|
0.00 |
|
|
| Unit running the course |
Instytut Elektroniki |
| Course coordinator |
dr inż. Aleksandra Królak |
| Course instructors |
dr inż. Michał Bujacz, dr inż. Marek Ossowski |
| Prerequisites |
no |
| Course learning outcomes |
- Perform DC and AC analysis in the frequency domain, compute and measure different powers in AC circuits, analyze first order circuits (BET1A_W1_N).
- Describe properties and behavior of diodes, transistors and basic electronic circuits (BET1A_W1_N).
- Manufacture simple circuits on PCB (BET1A_U2_N).
- Using computer programs and apply basic techniques of measurement and instrumentation for circuit analysis (BET1A_U2_N).
|
| Programme learning outcomes |
- The student knows and understands the basic problems and directions of civilization development, including the impact of the development of technology and technology on its progress.
- The student can make the right selection of information sources, evaluate, critically analyze and synthesize this information, select and apply appropriate methods and tools, including advanced information and communication techniques, can use knowledge in the field of formulating and solving complex and unusual engineering problems, including performing tasks in new conditions.
|
| Programme content |
To provide an introduction to electric and electronic devices and circuits, including circuit analysis, application of computer programs and manufacturing as well as basic techniques of measurement and instrumentation. |
| Assessment methods |
1-4 Current checking of knowledge and skills.
1-4 Laboratory reports prepared by the students.
1-2 Mid semester tests.
1-2 Written examination.
|
| Grading policies |
Electrical Eng. part: written examination 35%, class-work 9%, lab. experiments 6%.
Electronics part: written examination - 35%, class-work 8%, lab. experiments 7%. |
| Course content |
LECTURE
Electric circuits, elements and models. The Kirchhoff voltage and current
laws. Linear and nonlinear resistors. Simple resistive circuits. DC operating
points. Superposition theorem. The Thevenin-Norton theorem. Node
analysis of resistive circuits. Capacitors and inductors, memory, continuity
property. First order dynamic circuits, transient analysis. Sinusoidal
steady-state analysis, phasor concept. Power and energy. Resonant circuits.
Electronic circuits and their functions. Signals and
their spectra. Amplifiers - basic concepts. RC filters. Load line analysis.
Diode circuits, Zener diode, voltage regulator. Bipolar transistors (BJT).
Field Effect Transistors (FETs) operation, Junction Field Effect Transistor
(JFET). Metal-Oxide-Semiconductor FETs (MOSFETs). Fixed- and self-bias
circuits. Simple amplifier circuits.
TUTORIALS
Simple resistive circuits. The superposition theorem. Applications of the
Thevenin - Norton theorem. Node method. Capacitors and inductors.
Transient analysis of RL and RC circuits. AC analysis of sinusoidal circuits
using the phasor concept. Calculation of power in sinusoidal steady-state.
Diode and transistor circuit analysis. Load line analysis. Amplifier circuits.
LABORATORY
The measurements of voltage, current and resistance. Verification of basic
laws and principles of circuit theory. Resonant circuits. First order dynamic
circuits. Three-phase systems. Diode rectifier circuits and operational
amplifier circuits. Computer aided analysis. Circuit manufacture on PCB. |
| Basic reference materials |
- Tadeusiewicz M., Electric circuits, textbook, IFE, Łódź 2009.
- Tadeusiewicz M., Electric circuits, Tutorial problems, IFE, Łódź 2010.
- Materka A., Analog Electronics, Technical University of Lodz, Faculty of Electrical and Electronic Engineering, 1998, ISBN 83-87202-06-1.
|
| Other reference materials |
- Tadeusiewicz M., Electric circuits, textbook, IFE, Łódź 2009.
- Tadeusiewicz M., Electric circuits, Tutorial problems, IFE, Łódź 2010.
- Materka A., Analog Electronics, Technical University of Lodz, Faculty of Electrical and Electronic Engineering, 1998, ISBN 83-87202-06-1.
|
| Average student workload outside classroom |
60 |
| Comments |
no |
| Updated on |
2023-09-16 12:36:54 |
| Archival course yes/no |
no |