| Course Unit Code | 440-2101/01 |
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| Number of ECTS Credits Allocated | 6 ECTS credits |
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| Type of Course Unit * | Compulsory |
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| Level of Course Unit * | First Cycle |
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| Year of Study * | First Year |
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| Semester when the Course Unit is delivered | Winter Semester |
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| Mode of Delivery | Face-to-face |
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| Language of Instruction | Czech |
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| Prerequisites and Co-Requisites | There are no prerequisites or co-requisites for this course unit |
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| Name of Lecturer(s) | Personal ID | Name |
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| TES10 | Ing. Zdeněk Tesař |
| WIT005 | Ing. Karel Witas, Ph.D. |
| Summary |
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| Fundamental conceptions, electric circuit law and solving methods. passive element characteristics and utilization, passive RC, RL and RLC circuits solving. signal characteristics and description. semiconductor component characteristics and characterization, diodes, transistors, thyristors, operational amplifiers, optoelectronic elements. amplifier parameters and design, switches, flip-flop circuits with transistors, Integrated Circuits and operational amplifier. voltage and current supply characteristics, rectifiers with collective capacitor, linear and impulse voltage rectifiers D/A and A/D converter principles. optoelectronic element application. |
| Learning Outcomes of the Course Unit |
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Understand the basic electronic circuit and their function.
Learning outcomes are set so that the students are able to identify and apply fundamental role in the field of electronic circuits.
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| Course Contents |
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Lectures:
Basic concepts. Voltage, current,
power, labour, ohm's law, Kirchhoff's circuit laws. Source voltage and
current. The methods of solving electrical circuits. Signals.
Properties and the use of passive
R, L, C elements. Impedance and admittance. Resonant circuits.
Double gates circuits. Circuit
function, frequency, transient and impulse characteristics. Basic passive
RC, RL and RLC two-ports.
Double gates circuits. Controlled
resources, ideal amplifier voltage and current, ideal operational amplifier,
the ideal transformer.
Semiconductor diodes and thyristors.
The characteristics and parameters, circuit models. Rectifiers, switches,
limitation and parametric stabilizers.
Transistors. Features and
parameters bipolar and unipolar transistors, the working point, circuit
models.
Basic involvement of transistors.
Amplifiers and switching circuits.
Principle Backward linkages and its
impact on the characteristics of electronic circuits.
Operational amplifiers. Principle
and characteristics, the fundamental involvement.
The application of operational
amplifiers. Amplifiers, filters, generators and comparators.
Stabilizers voltage and current.
Properties, through the implementation of discrete components and integrated
circuits.
Pulse resources. The principle and
basic involvement.
The principles and characteristics
of D / A and A / D converters.
Optoelectronic prvky.Principls and properties.
Exercises:
Work safety in the laboratory,
laboratory schedule, the conditions of granting credit. Entering projects P1, P2.
Proposal RL and RC circuits (integration and derivative articles). Frequency and transient Test No knowledge
Laboratories:
Design and measurement of voltage and current dividers.
Measurement properties rezonans serial and parallel circuits.
Measurement of the characteristics of integration and derivation article.
Measurement of VA characteristics of semiconductor diodes.
Measurement of VA characteristics and parameters bipolar and unipolar transistors.
Measurement Measurement parameters DC transistor amplifiers and switches.
Measurement properties AC transistor amplifiers.
Design and measurement of parameters the operational AMPLIFIERS.
The measurement parameters and characteristics of parametric voltage stabilizer.
Implementation and verification of functional integration project P1.
Implementation and verification of functional integration project P2. |
| Recommended or Required Reading |
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| Required Reading: |
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Storey N.: Electronics : a systems approach, Pearson Education, Harlow, 2013
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Vobecký,J.,Záhlava, V. :Elektronika, součástky a obvody, principy a příklady.
Grada Publishing Praha 2001, ISBN 80-7169-884-9
BRANDŠTETTER, Pavel, et al. Elektronika - prvky elektronických obvodů. Vyd. 1. Ostrava : Ediční středisko VŠB-TUO, 2007. 142 s. ISBN 978-80-248-1481-0.
VEDRAL, Josef, FISCHER, Jan. Elektronické obvody pro měřicí techniku. Praha :Vydavatelství ČVUT, 1999. 340 s. ISBN 80-01-01950-0.
MOHYLOVÁ‚ J. a J. PUNČOCHÁŘ‚ 2007. Cvičení z elektrických obvodů I. Ostrava: Vysoká škola báňská - Technická univerzita Ostrava.
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| Recommended Reading: |
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| Tietze U., Schenk Ch., Gamm E.: Electronic circuits : handbook for design and application, Springer, Berlin, 2008 |
Punčochář, J.: Operační zesilovače v elektronice. Praha, BEN 1996
Punčochář, J.: Lineární obvody s elektronickými prvky. VŠB - TU Ostrava, Ostrava 2002
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| Planned learning activities and teaching methods |
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| Lectures, Tutorials, Experimental work in labs |
| Assesment methods and criteria |
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| Task Title | Task Type | Maximum Number of Points
(Act. for Subtasks) | Minimum Number of Points for Task Passing |
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| Exercises evaluation and Examination | Credit and Examination | 100 (100) | 51 |
| Exercises evaluation | Credit | 40 | 20 |
| Examination | Examination | 60 (60) | 11 |
| PZ | Written examination | 50 | 0 |
| ÚZ | Oral examination | 10 | 0 |