Basics of electronics
Course: Physics
Structural unit: Faculty of Physics
Title
Basics of electronics
Code
ОК 33.
Module type
Обов’язкова дисципліна для ОП
Educational cycle
First
Year of study when the component is delivered
2021/2022
Semester/trimester when the component is delivered
2 Semester
Number of ECTS credits allocated
5
Learning outcomes
Be able to apply basic mathematical knowledge used in electronics. Understand, analyze and explain results obtained during physical experiments. Have basic skills of self-study: be able to find the necessary information in printed and electronic sources.
Form of study
Full-time form
Prerequisites and co-requisites
The student must know the basic fundamental laws of electromagnetic phenomena. On the importance of assessing the accuracy of the results obtained and the source of probable errors. About safety rules during experimental research. The student must be able to: Present and analyze the results. Work with simple experimental equipment, and estimate measurement errors. Process and explain the obtained results. Evaluate the orders of magnitude of the studied quantities, their accuracy, and degree of reliability, calculate measurement errors and formulate conclusions. Independently work with educational, teaching, and reference literature on electronics.
Course content
Radio electronics in a physical experiment. Computer simulation in radio electronics. Elements of electronic circuits and methods of analysis of these circuits. Transients, frequency characteristics, and resonances in linear circuits. Energy zones in a solid body. Contact phenomena. Electronic devices with one rectifying transition. Bipolar and channel field-effect transistors. Insulated gate transistors and coupled devices. Classification and main characteristics of transistor amplifiers. Circuits of amplifiers on transistors. Operational amplifiers. Harmonic oscillation generators. Pulse generators.
Recommended or required reading and other learning resources/tools
1. В.А. Kizel. Optical activity and asymmetry of living systems // UFN v.131, up. 2, 1980, p. 209-238.
2. V.A. Kizel. The induction of gyrotropy is a new research method in the physics of condensed matter. // UFN t.147, issue. 3, 1985, p. 559-585
3. O.V. Slobodyanyuk. Effects of spatial dispersion in the spectra of phonon Raman scattering in gyrotropic crystals. // Bulletin of the University of Kyiv, Series: Phys.-Math. Science, №4, 2006.
4. Modern Techniques for Circular Dichroism and Synchrotron Radiation Circular Dichroism Special Trousers. B.A. Wallace and R.W. Janes (Ed.) // IOS Press, 2009
5. OV Slobodyanyuk. Lecture materials, methodical and additional materials for independent study and independent work // Available at ftp://ftp.univ.kiev.ua/.incoming/Chiral_2014.
Planned learning activities and teaching methods
Lectures, laboratory work.
Assessment methods and criteria
Evaluation is carried out on a 100-point modular rating system. It consists of two modules. Forms of student assessment:
- semester assessment:
1. Modular tests, colloquia, and defense of independent work - 20 points.
2. Execution of laboratory works and protection of reports on laboratory works - 20 points. An applicant is not allowed to take the exam if he/she scored less than 24 points during the semester.
- final evaluation:
in the form of an exam. The maximum number of points is 60.
Language of instruction
Ukrainian
Lecturers
This discipline is taught by the following teachers
Yrii
Oleksandrovych
Miagchenko
Department of Experimental Physics
Faculty of Physics
Faculty of Physics
Departments
The following departments are involved in teaching the above discipline
Department of Experimental Physics
Faculty of Physics