Faculty of Information Technology, BUT

Course details

Electronics for Information Technology

IEL Acad. year 2019/2020 Winter semester 6 credits

Basic transient analysis of electric circuits. Formulation of circuit equations and possibilities of their solutions. Analysis of RC, RL, and RLC circuits. Analysis of non-linear electric circuits. Parameters and characteristics of semiconductor elements. Graphic, numerical, and analytical methods of non-linear circuit analysis. TTL and CMOS gates. Power supply units. Limiters and sampling circuits. Level translators, stabilizers. Astable, monostable, and bistable flip-flops. Lossless and lossy transmission lines. Wave propagation on transmission lines, reflections, impedance matching.


Deputy Guarantor

Language of instruction



Credit+Examination (written)

Time span

39 hrs lectures, 6 hrs exercises, 12 hrs laboratories, 8 hrs projects

Assessment points

55 exam, 15 half-term test, 18 labs, 12 projects




Course Web Pages

Subject specific learning outcomes and competences

Ability to analyse electric circuits with practical application in computer science.
Knowledge of safety regulations for work with electronic devices.

Learning objectives

To obtain general knowledge and basics of selected methods of description and analysis of electric circuits with practical application in computer science. To obtain detailed instructions and information about occupational safety with electric devices. To gain practical knowledge of working with fundamental electronic circuits in labs.

Why is the course taught

Even though the software is immaterial, the humanity has to still use matter to express and store thoughts, ideas and solutions. Systems designed to store the information are very complicated and have to be miniaturized. And because everything is still made of matter, we need forces that can manipulate even small particles of matter. Electromagnetic fields contain such sources, so we can, using smartly designed circuits, focus the energy and manipulate it very precisely. This is why computers are based on electronics. To understand how the computers work, we need to understand basic laws that govern electric field, electric circuits. This knowledge can then be useful when designing more complicated (for the most part digital) electronic circuits. 

Prerequisite kwnowledge and skills

This course takes place in the winter term of the first year of the bachelor's study programme. Thus, we expect that students have the high school level knowledge.

Study literature

  • Blahovec, A.: Elektrotechnika I, II, III, Informatorium, Praha 2000
  • Gescheidtová, E.: Základní metody měření v elektrotechnice. Brno, CERM 2000.
  • Láníček, R.: ELEKTRONIKA, obvody-součástky-děje, BEN - technická literatura, Praha 1998
  • Punčochář, J.: Operační zesilovače v elektronice, BEN - technická literatura, Praha 1999

Fundamental literature

  • Lecture notes written in PowerPoint
  • Murina, M.: Teorie obvodů. Brno, VUTIUM 2000.
  • Brančík, L.: Elektrotechnika I. Brno, skripta FEKT VUT.
  • Sedláček, J., Dědková, J.: Elektrotechnika I - laboratorní a počítačová cvičení. Brno, skripta FEKT VUT.
  • Sedláček, J., Valsa, J.: Elektrotechnika II. Brno, skripta FEKT VUT.
  • Murina, M., Sedláček, J.: Elektrotechnika II - počítačová cvičení. Brno, skripta FEKT VUT.
  • Horowitz, P., Hill, W.: The art of electronics 3rd edition, Cambridge University Press, 2015.

Syllabus of lectures

  1. The mathematical basis for electric circuits (analytic and numerical methods), terminology and quantities used in circuits.
  2. Laws in linear DC circuits (Ohm's Law, Kirchhoff's law)
  3. Electrical circuits of resistors with one and more directed voltage sources, analysis based on a method of simplification
  4. Theorems about substituted sources (Thévenin's theorem), a method of loop's current and nodes voltages, the superposition principle
  5. General description of RC, RL and RLC circuits. RC, RL and RLC circuits with sources of direct voltage. Transient processes
  6. Alternating voltages and Fourier's series, a solution of RLC circuits. RLC circuits in impulse mode, frequency filters
  7. Lossless and lossy transmission lines. Wave propagation in transmission lines.
  8. Semiconducting components, bipolar technology, PN junction, diode
  9. Bipolar transistors, transistor as a switch
  10. Unipolar transistors, TTL and CMOS gates (logic levels, power consumption)
  11. Operational amplifiers with weighted resistant nets. Digital-to-analogue converters. Analogue-to-digital converters
  12. Overview of important electric circuits (voltage sources, stabilizers, oscillator, multivibrator, bi-stable flip-flop, Schmitt flip-flop, timer, comparator, transmitter, receiver). Microelectronics, principles of integrated circuits manufacturing
  13. Methods of measurement of electric and non-electric quantities. Modern measuring devices. Principles and application of measuring devices

Syllabus of numerical exercises

  1. Electric circuits of resistors. Fundamental circuits. Editor and simulator of electric circuits with directed voltage source. Audiovisual demonstrations
  2. RLC circuits, transient processes. Fundamental circuits. Editor and simulator of RLC circuits with alternating voltage source. Audiovisual demonstrations
  3. Bipolar technology, diode. Fundamental circuits. Audiovisual demonstrations
  4. Bipolar technology, transistor. Fundamental circuits. Audiovisual demonstrations
  5. A/D a D/A converters. Audiovisual demonstration of manipulation with professional electronic devices
  6. Signal transmission. Fundamental circuits. Audiovisual demonstrations

Syllabus - others, projects and individual work of students

Individual valorization of the course on a chosen examples from areas:
  1. Loop Current Method
  2. Nodal Voltage Analysis
  3. Thévenin's theorem
  4. Transient events in RLC circuits

Progress assessment

During the semester, 6 laboratories (each for a maximum of 3 points), semestral project (max. 12 points) and mid semester exam (maximum 15 points) are assessed.

Controlled instruction

Mid-term exam and Final exam: The minimal number of points which can be obtained from the final exam is 27. Otherwise, no points will be assigned to a student. Laboratories are voluntary. The missed laboratory is possible to replace with the individual project after consultation with the lecturer.

Exam prerequisites

  • The necessity of complete an electrical safety training course (compliant with Decree No 50/1978)
  • Obtain at least 3 points from the semester project and at least 6 points from laboratories.


Monlecturelectures D0206 D105 11:0012:50 1BIA 2BIA 2BIB xx
Moncomp.lablectures L306 13:0014:50 1BIA
Moncomp.lablectures L306 15:0016:50 1BIB
Moncomp.lablectures L306 17:0018:50 1BIB
Moncomp.lablectures L306 19:0020:50 1BIA 1BIB
Wedcomp.lablectures L306 07:0008:50 1BIB
Wedlecturelectures E104 E105 E112 09:0010:50 1BIB 2BIA 2BIB xx
Wedcomp.lablectures L306 09:0010:50 1BIA
Wedcomp.lablectures L306 11:0012:50 1BIB
Wedlecturelectures D0207 D105 14:0014:50 1BIA 2BIA 2BIB xx
Wedexerciselectures D0207 D105 15:0015:50 1BIA 2BIA 2BIB xx 10 - 29
Thucomp.lablectures L306 12:0013:50 1BIB
Thulecturelectures E104 E105 E112 14:0014:50 1BIB 2BIA 2BIB xx
Thucomp.lablectures L306 14:0015:50 1BIA
Thuexerciselectures E104 E105 E112 15:0015:50 1BIB 2BIA 2BIB xx 30 - 44
Thucomp.lablectures L306 16:0017:50 1BIA 1BIB
Thucomp.lablectures L306 18:0019:50 1BIA 1BIB
Fricomp.lablectures L306 07:0008:50 1BIA 1BIB
Fricomp.lablectures L306 09:0010:50 1BIA 1BIB
Fricomp.lablectures L306 11:0012:50 1BIA
Fricomp.lablectures L306 13:0014:50 1BIA

Course inclusion in study plans

  • Programme BIT, 1st year of study, Compulsory
  • Programme IT-BC-3, field BIT, 1st year of study, Compulsory
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