Electronic Circuits
Code  Completion  Credits  Range  Language 

F7ABBEO  Z,ZK  4  2P+2C  English 
 Vztahy:
 In order to register for the course F7ABBEO, the student must have successfully completed the course F7ABBTEL in a previous semester.
 In order to register for the course F7ABBSM, the student must have successfully completed or received credit for and not exhausted all examination dates for the course F7ABBEO.
 In order to register for the course F7ABBPNK, the student must have successfully completed the course F7ABBEO.
 The course F7ABBSEL can be graded only after the course F7ABBEO has been successfully completed.
 Garant předmětu:
 Pavel Máša
 Lecturer:
 Pavel Máša
 Tutor:
 Tomáš Dřížďal, Ondřej Fišer, Pavel Máša, Marek Novák
 Supervisor:
 Department of Biomedical Technology
 Synopsis:

The course provides a basic orientation in the principles of electronic circuits used in electronic laboratory and medical devices. It provides a prerequisite for the skilled operation of analogue and digital instrumentation.
technology.
Course entry requirements:
Successful completion of Theoretical Electrical Engineering.
Exit Knowledge, Skills, Abilities and Competencies:
Students will become familiar with functional electronic blocks that are used in the design of laboratory and medical instruments. The course will prepare them to competently assess the basic properties and parameters of electronic devices.
 Requirements:

The examination evaluation is composed of the points gained during the semester, the scores of the written part of the examination and the evaluation of the interview, which is part of the examination.
A condition for entry to each of the laboratory measurements is to pass an entry quiz consisting of two questions (see PDF below for a full list of questions including the conditions for passing the test).
Students will turn in a report of one of the lab measurements no later than January 4, 2024. Reports submitted after this date will not be considered. Protocols will be graded from 0 to 10 points. In case of a score lower than 5 points, the protocol will be returned for revision. The maximum score that can be obtained after reworking is 5 out of 10.
 Syllabus of lectures:

1. Amplifier  voltage, current, power amplification, AC and DC coupling
2. Feedback  positive, negative, effect of ZV on amplifier parameters
3. Operational amplifier  ideal circuit element
4. Real operational amplifier  static parameters, dynamic parameters, frequency dependence
5. DC power supplies  batteries, accumulators, rectifiers, inverters
6. Comparator  basic parameters, electronic circuit of comparator,
7. Shape oscillator, sine wave oscillator LC and RC, voltage controlled oscillator (VCO)
8. Combinatorial logic function  forms of combinatorial function notation
9. Sequential logic function  synchronous and asynchronous operation of a sequential circuit
10. Integrated semiconductor logic functions  technological families of semiconductor logic circuits electrical parameters
11. Semiconductor memories  format of stored data, chip and memory block capacity
12. Data storage principle  memory cell permanent, quasipermanent, volatile static and dynamic
13. Analog signal transmission and processing chain, sampling frequency, quantization
14. Basic principles of A/D and D/A conversion, resistive D/A converter, PWM D/A converter
 Syllabus of tutorials:

1. Repetition of the basics of theoretical electrical engineering  circuit quantities, elements, basic laws. Amplifier  amplification
voltage, current, power, frequency dependence
2. Operational amplifier  ideal circuit element, basic structures of amplifiers, calculation of amplification, integrator.
3. Basic calculations in circuits with ideal operational amplifier. Introduction to means for experiments with
electronic components
4. Real operational amplifier  static and dynamic parameters. Parameters of the most common integrated operational amplifiers.
amplifiers. Special operational amplifiers. LAB  Verification of DC characteristics of an operational amplifier circuit.
OP 27. Connection of inverting and noninverting circuit, connection of summing circuit. Verification of real
ratios at the terminals of the circuit.
DC power supplies  batteries, accumulators, rectifiers, stabilisers, calculations of required
diode parameters, orientation in catalogue data Measurements on a simple rectifier and stabilising circuit with
Zener diode.
6. DC power supplies  switching power supplies and converters, charge pump. Description of operation, characteristics
integrated circuits from catalogues. LAB  Wiring and basic measurements on a threesource regulator and DC/DC
converter.
7. Comparator  parameters, use of OZ, comparator with hysteresis  calculation, generators  calculation, oscillators  calculation.
8. Combinational logic functions  forms of notation, algebra, logical terms, elementary operations in algebra of logic functions.
LAB  Constructing a combinational circuit according to a given truth table. Verification.
9. Integrated logic members  elementary NAND and NOR members, integrated logic functions, el. parameters
10. Sequential logic function  synchronous and asynchronous operation of sequential circuit. LAB  Building a sequential
circuit  counter in Gray code
11. Semiconductor memories  data format, capacity, data access, data storage principle. Address decoding in an array.
memory chips.
 Study Objective:

The course provides a basic orientation in the principles of electronic circuits used in electronic laboratory and medical devices. It creates a prerequisite for qualified operation of analogue and digital instrumentation.
 Study materials:
 Note:
 Timetable for winter semester 2024/2025:

06:00–08:0008:00–10:0010:00–12:0012:00–14:0014:00–16:0016:00–18:0018:00–20:0020:00–22:0022:00–24:00
Mon Tue Wed Thu Fri  Timetable for summer semester 2024/2025:
 Timetable is not available yet
 The course is a part of the following study plans:

 Prospectus  bakalářský (!)
 Biomedical Technology (compulsory course)