| Course code |
02 05 6304 00 |
| Number of ECTS points |
4 |
| Course title in the language of instruction |
Electrical & Electronic Engineering |
| Course title in Polish |
Electrical and Electronic Engineering (Elektrotechnika i elektronika) |
| Course title in English |
Electrical & Electronic Engineering |
| Language of instruction |
English |
| Form of classes |
|
Lecture |
Tutorials |
Laboratory |
Project |
Seminar |
Other |
Total of teaching hours during semester |
| Contact hours |
30 |
|
30 |
|
|
0 |
60 |
| E-learning |
No |
No |
No |
No |
No |
No |
|
| Assessment criteria (weightage) |
0.50 |
|
0.50 |
|
|
0.00 |
|
|
| Unit running the course |
Instytut Systemów Inżynierii Elektrycznej |
| Course coordinator |
dr inż. Marek Ossowski |
| Course instructors |
dr hab. inż. Stanisław Hałgas, dr inż. Ewa Korzeniewska, dr inż. Marek Korzybski, dr inż. Marcin Lebioda, dr inż. Marek Ossowski, dr hab. inż. Ryszard Pawlak, dr inż. Arkadiusz Tomczyk, dr inż. Maria Walczak |
| Prerequisites |
Basic knowledge from mathematics and physics. Complex numbers, sets of linear equations. |
| Course learning outcomes |
- Students know and understand funcionality of basis electric and electronic circuits, computer measurement systems and most importatnt methods of circuit analysis (W01)
- A student is able to perform experiments in electotechnics, including measurements and simulatons and can write reports and work in laboratoety teams realising particular tasks (U04)
|
| Programme learning outcomes |
|
| Programme content |
Basic information of electric circuits. Fundamental laws and methods of circuit analysis inn steady adn transient ststes. Semiconductors and semicondustor devices, logic gates. Functions of choosen computer systems elememts. Fundamentals of measurement techniques. Introduction to computer programmes using in computer simulation of electric and electronic circuits. |
| Assessment methods |
1. final lecture exam - two theoratical problems, comupation task and single choice test (written, 45 min.)
2. laboratorium - checking preparation for clasess, activity diuring labratory classes, raports.
|
| Grading policies |
Lecture: 50% of maximal points of the written exam
Laboratory: written or werbal form of chechecking the knowledge, grade for report. |
| Course content |
Lecture:
Fundamentals definitions and concepts : electric and magnetic fields, signals, current, voltage, power, energy, symbols and units of electrical quantities, typical values. Basic information of circuit elements: resistor, inductor, capacitor, voltage and current sources, diode, transistors. Fundamental laws and methods for circuit analysis: Ohms law, Kirchhoff?s laws, superposition method, node voltage method. Chosen practical applications of circuit elements and their effect on the circuit operation: resistor as a current limiter, MOS transistor as a switch, charging and discharging capacitor, time constant, storage energy, effect of capacitor on the shape of signal timing, resonance phenomenon, LC circuits in transceiver devices. Wave ranges and technologies applies in wireless communication. Fundamentals of modulation. Introduction to electronics: conductors, doped and intrinsic semiconductors, isolators. Basic semiconductor devices: diode, MOS transistor. Selected logic gates.
Laboratory:
Verification of basic laws of electrical engineering in a physical laboratory (Ohm's law, Kirchhoff's law, characteristics of an real voltage source). Investigation of the influence of RC circuits on electronic signals, including: square wave distortion, low-pass filtering. The phenomenon of resonance in electronic systems - determining the parameters of resonance circuits, applications in receiving systems. The use of PWM modulation to control the fan speed and lighting control. Materials used to manufacture functional components of the computer. Information read and write - magnetic, optical and semiconductor data storage systems. Information visualization techniques - LCD, OLED displays, projectors. Measurements of basic electrical quantities, accuracy of measuring instruments, measurement uncertainty. Transducers of non-electric quantities (sensors of environmental parameters, position and displacement). Analog-to-digital converters, bit resolution, quantization error.
|
| Basic reference materials |
- Tadeusiewicz M., Teoria Obwodów, cz.I, Wyd. PŁ, Łódź 2003.
- Horowitz P., Hill W., Sztuka Elektroniki, cz.1,2 WKŁ Warszawa 2014.
- Celiński Z.: Materiałoznawstwo elektrotechniczne, wydanie 4, Oficyna Wydawnicza PW, Warszawa, 2011.
- Chwaleba A., Poniński M., Siedlecki A.: Metrologia elektryczna, WNT, Warszawa 2010.
- Lyons R.: Wprowadzenie do cyfrowego przetwarzania sygnałów, WKŁ, Warszawa 2010.
- Nawrocki W.: Komputerowe systemy pomiarowe, WKŁ, Warszawa 2006
|
| Other reference materials |
- Agrawal A., Lang J.H., Foundations of Analog and Digital Electronic Circuits, Elsevier,San Francisco, 2005.
- Horowitz P., Hill W., The Art of Electronics, 3rd ed., Cambridge University Press 2015.
- Osowski S., Siwek K., Śmiałek M., Teoria Obwodów - podręcznik multimedialny, Oficyna Wydawnicza PW, Warszawa 2006.
|
| Average student workload outside classroom |
55 |
| Comments |
|
| Updated on |
2021-05-10 00:15:05 |
| Archival course yes/no |
no |