FPF:UFMM501 Physical basics of electronics - Course Information
UFMM501 Physical basics of electronics II
Faculty of Philosophy and Science in OpavaSummer 2014
- Extent and Intensity
- 2/2/0. 4 credit(s). Type of Completion: zk (examination).
- Teacher(s)
- Ing. Miroslav Vala, CSc. (lecturer)
Ing. Miroslav Vala, CSc. (seminar tutor) - Guaranteed by
- Ing. Miroslav Vala, CSc.
Centrum interdisciplinárních studií – Faculty of Philosophy and Science in Opava - Prerequisites (in Czech)
- Znalosti základního kursu Fyzikální základy elektroniky I na úrovni zápočtu
- Course Enrolment Limitations
- The course is also offered to the students of the fields other than those the course is directly associated with.
- fields of study / plans the course is directly associated with
- Multimedia Technologies (programme FPF, B1702 AplF)
- Course objectives
- The course will provide students with basic knowledge in the field of passive and semiconductor devices and their properties, including elemental design of simple electronic circuits and verification in practical involvement. The course is designed as preparatory for other items base on the basic knowledge of electronics.
- Syllabus
- Unipolar J FET transistors and a MOS FET. Specifics of the activity field effect transistors. Characteristic parameters. Characteristics of FET transistors. Area enrichment and impoverishment. Basic connection of FET transistors. MOS FET transistor with two control electrodes (tetrode), descriptions of the properties and applications of RF. Power MOSFET characteristics, features and comparison with bipolar transistor applications.
Switching the semiconductor devices with multiple transitions and their characteristics VA. Double base diode (UJT transistor) Diak. Basic properties VA characteristics, application. Thyristor and triac. Basic properties VA characteristics. Switching on and off thyristors. The basic connection and use.
Semiconductor devices and components using semiconductor materials without any particular properties defined by the PN (varistors, thermistors, photoresistors, etc.)
The principle of feedback. Feedback in amplifiers, types of feedback, technical meaning. Differential stage and its properties. Operating system (realized feedback in OZ) and its significance.
Operational amplifiers (OA). Basic properties and characteristics of ideal and real OZ. Basic connection with Mark as amplifiers, rectifiers operating and carrying out mathematical operations on the el. signals (addition, subtraction, multiplication, division, logarithm (exp. FCE). integration and differentiation, and composite functions. basics control (automation) PID controller. Implementation lower, upper and band-pass filter.
The principle of wireless transmission. Spread solenoid. waves of different frequencies. Signal path (transmitter (encoder) transmission channel receiver (decoder). Maximum transmission capacity of the communication channel (Shannon-Hartley). Principle antenna. Basic types of modulation (AM, FM, PCM, etc.). Reception and processing of RF signals, superheterodyne principle). The principle of digitization.
Fundamentals of digital technology. Boolean algebra and its basic laws (Boolean identity) for one and two variables. The basic logic elements and their implementation NAND and NOR. Basic logic gates logical construction TTL 74XX Series (NAND function), CMOS logic gates. Combinational and sequential logic circuits.
- Unipolar J FET transistors and a MOS FET. Specifics of the activity field effect transistors. Characteristic parameters. Characteristics of FET transistors. Area enrichment and impoverishment. Basic connection of FET transistors. MOS FET transistor with two control electrodes (tetrode), descriptions of the properties and applications of RF. Power MOSFET characteristics, features and comparison with bipolar transistor applications.
- Literature
- recommended literature
- Bezděk, Miloslav. Elektronika II - učebnice. KOPP, 2003. ISBN 80-723-2212-5. info
- Kesl Jan. Elektronika 1 analogová technika. BEN, 2003. ISBN 80-7300-074-1. info
- Peček Jiří. Elektronika v kostce. BEN, 2002. ISBN 80-86056-80-5. info
- M. Vala. Fyzikální základy elkrotechniky a elektroniky I. Ostravská Universita, 2002. ISBN 80-7042-239-4. info
- M. Vala. Základy elektrotechniky a elektroniky - úvod do teorie obvodů. Ostravská univerzita, 2002. info
- Malina, Václav. Poznáváme elektroniku VI - od A do Z. KOPP, 2001. ISBN 80-723-2146-3. info
- Láníček Robert. Elektronika obvody - součástky - děje. BEN, 1999. ISBN 80-860-5625-2. info
- Dietmeier, Ulrich. Vzorce pro elektroniku. BEN, 1999. ISBN 80-860-5653-8. info
- Malina, Václav. Poznáváme elektroniku I. KOPP, 1998. ISBN 80-723-2039-4. info
- Malina, Václav. Poznáváme elektroniku II. KOPP, 1998. ISBN 80-858-2887-1. info
- Malina, Václav. Poznáváme elektroniku III. KOPP, 1998. ISBN CPISBN79. info
- Brandštetter P. Elektronika. Skripta VŠB, Ostrava, 1991. info
- J. Stránský a kol. Praha. Polovodičová technika I., II. 1973-82, SNTL, Praha, 1973. info
- Teaching methods
- Interactive lecture
One-to-One tutorial
Laboratory work - Assessment methods
- Credit
- Language of instruction
- Czech
- Further comments (probably available only in Czech)
- The course can also be completed outside the examination period.
- Teacher's information
- * Participation in exercises 75%, approved by admitable excuse, additional homework replacement.
* Preparation of seminar work of exercise (theoretical part to the practices)
* Successful passing of a written and oral examination (two questions taken).
*
- Enrolment Statistics (recent)
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