Fundamentals of electronic measuring equipment
Description: Introduction to the fundamentals of physical electronics, disclosure of the essence of physical phenomena and processes that determine the operating principle and parameters of a large number of electronic, ionic and semiconductor devices used in the development and manufacture of various devices and apparatus. Formation of the ability to reasonably select one or another type of device depending on the area of specific application and operating conditions.
Amount of credits: 6
Пререквизиты:
- Introduction to engineering
Course Workload:
| Types of classes | hours |
|---|---|
| Lectures | 30 |
| Practical works | |
| Laboratory works | 30 |
| SAWTG (Student Autonomous Work under Teacher Guidance) | 30 |
| SAW (Student autonomous work) | 90 |
| Form of final control | Exam |
| Final assessment method | Exam |
Component: Component by selection
Cycle: Base disciplines
Goal
- to introduce the basics of physical electronics, to reveal the essence of physical phenomena and processes that determine the operating principle and parameters of a large number of electronic, ionic and semiconductor devices used in the development and manufacture of various devices and apparatus. To develop the ability to reasonably choose one or another type of device depending on the specific area of application and operating conditions.
Objective
- Obtaining knowledge about the physical principles of operation, characteristics, parameters, models of the main types of active devices, their operating modes in radio circuits and devices, the fundamentals of the technology for the production of electronic products and the principles of constructing basic cells of integrated circuits, the mechanisms of influence of operating conditions on the operation of active devices and electronic products ;
Learning outcome: knowledge and understanding
- It is planned to use the following educational technologies during the training sessions - It is intended to use the following educational technologies during the training sessions: - interactive lecture (using the following active forms of teaching: leading (controlled) discussion or conversation; moderation; showing slides or educational films; brainstorming; motivational speech); - creation of development scenarios of various situations based on given conditions; - information and communication (for example, lessons in a computer class using professional packages of application programs); - search-research (individual research activity of students during the learning process);
Learning outcome: applying knowledge and understanding
- - remove the main characteristics of semiconductor devices, amplifiers and determine the parameters of various electronic circuits, select the base of elements.
Learning outcome: formation of judgments
- organize the process of developing and implementing software systems for automated control systems for various production facilities;
Learning outcome: communicative abilities
- formulate problems and presentations of the proposed design solution in the field of organizing work on the development and operation of microprocessor complexes in automation systems, both for specialists and non-specialists;
Learning outcome: learning skills or learning abilities
- As a result of the study, the student will have the skills to work with electrotechnical equipment and electronic devices; - skills of processing experimental data and evaluating the accuracy of tests
Teaching methods
interactive lecture (use of the following active forms of learning: guided (controlled) discussion or conversation; moderation; demonstration of slides or educational films; motivational speech);
information and communication (classes in a computer lab using professional software packages);
search and research (independent research activities of students during the learning process).
Assessment of the student's knowledge
Teacher oversees various tasks related to ongoing assessment and determines students' current performance twice during each academic period. Ratings 1 and 2 are formulated based on the outcomes of this ongoing assessment. The student's learning achievements are assessed using a 100-point scale, and the final grades P1 and P2 are calculated as the average of their ongoing performance evaluations. The teacher evaluates the student's work throughout the academic period in alignment with the assignment submission schedule for the discipline. The assessment system may incorporate a mix of written and oral, group and individual formats.
| Period | Type of task | Total |
|---|---|---|
| Total control | Exam | 0-100 |
The evaluating policy of learning outcomes by work type
| Type of task | 90-100 | 70-89 | 50-69 | 0-49 |
|---|---|---|---|---|
| Excellent | Good | Satisfactory | Unsatisfactory | |
| Interview on control questions | Demonstrates systematic theoretical knowledge, is proficient in terminology, logically and consistently explains the essence of phenomena and processes, makes reasoned conclusions and generalizations, gives examples, demonstrates fluency in monologue speech and the ability to quickly respond to clarifying questions | Demonstrates solid theoretical knowledge, has a command of terminology, logically and consistently explains the essence of phenomena and processes, makes reasoned conclusions and generalizations, gives examples, demonstrates fluency in monologue speech, but at the same time makes minor mistakes that are corrected independently or with minor correction by the teacher | Demonstrates shallow theoretical knowledge, displays poorly developed skills in analyzing phenomena and processes, insufficient ability to make reasoned conclusions and give examples, demonstrates insufficiently fluent command of monologue speech, terminology, logic and consistency of presentation, makes mistakes that can only be corrected with correction from the teacher. | Demonstrates systematic theoretical knowledge, is proficient in terminology, logically and consistently explains the essence of phenomena and processes, makes reasoned conclusions and generalizations, gives examples, demonstrates fluency in monologue speech and the ability to quickly respond to clarifying questions |
| Work in practical classes | Completed the work in full, observing the required sequence of actions; the report is prepared in accordance with the requirements; correctly performs the error analysis. When answering questions, correctly understands the essence of the question, gives an accurate definition and interpretation of the main concepts; accompanies the answer with new examples, knows how to apply knowledge in a new situation; can establish a connection between the material being studied and previously studied material, as well as with material learned while studying other disciplines. | Completed the work according to the requirement for a grade of "5", but 2-3 shortcomings were made. The student's answer to the questions satisfies the basic requirements for an answer of 5, but was given without applying knowledge in a new situation, without using connections with previously studied material and material learned in studying other disciplines; one mistake or no more than two shortcomings were made, the student can correct them independently or with a little help from the teacher. | The work was not completed in full, but not less than 50% of the volume, which allows obtaining correct results and conclusions; errors were made during the work. When answering questions, the student correctly understands the essence of the question, but the answer contains individual problems in assimilation of the course questions that do not interfere with further assimilation of the program material; no more than one gross error and two shortcomings were made. | Completed the work in full, observing the required sequence of actions; the report is prepared in accordance with the requirements; correctly performs the error analysis. When answering questions, correctly understands the essence of the question, gives an accurate definition and interpretation of the main concepts; accompanies the answer with new examples, knows how to apply knowledge in a new situation; can establish a connection between the material being studied and previously studied material, as well as with material learned while studying other disciplines. |
| Boundary control | Milestone test: 18-20 points – knowledge demonstrated at a high level | Milestone test: 14-17 points – demonstrated knowledge at a basic level | Milestone test: 13-10 points – knowledge demonstrated at a satisfactory level | Milestone test: 18-20 points – knowledge demonstrated at a high level |
Evaluation form
The student's final grade in the course is calculated on a 100 point grading scale, it includes:
- 40% of the examination result;
- 60% of current control result.
The final grade is calculated by the formula:
| FG = 0,6 | MT1+MT2 | +0,4E |
| 2 |
Where Midterm 1, Midterm 2are digital equivalents of the grades of Midterm 1 and 2;
E is a digital equivalent of the exam grade.
Final alphabetical grade and its equivalent in points:
The letter grading system for students' academic achievements, corresponding to the numerical equivalent on a four-point scale:
| Alphabetical grade | Numerical value | Points (%) | Traditional grade |
|---|---|---|---|
| A | 4.0 | 95-100 | Excellent |
| A- | 3.67 | 90-94 | |
| B+ | 3.33 | 85-89 | Good |
| B | 3.0 | 80-84 | |
| B- | 2.67 | 75-79 | |
| C+ | 2.33 | 70-74 | |
| C | 2.0 | 65-69 | Satisfactory |
| C- | 1.67 | 60-64 | |
| D+ | 1.33 | 55-59 | |
| D | 1.0 | 50-54 | |
| FX | 0.5 | 25-49 | Unsatisfactory |
| F | 0 | 0-24 |
Topics of lectures
- Topic 1
- Theme 2
- Theme 3
- Theme 4
- Theme 5
- Theme 6
- Theme 7
- Theme 8
- Theme 9
- Theme 10
- Theme 11
- Theme 12
- Theme 13
- Theme 14
- Theme 15
Key reading
- 1 John Bird Electrical and Electronic Principles and Technology / third Edition Published by Elsevier Ltd. All rights reserved, 2007, UK 2 Denis L. Eggeston Basic Electronics for Scientists and engineers Occidental College, Los Angeles, Cambrodge University press, 2011 3 Albert Malvino, David J. Bates Electronic Principles, 7 Edition, 2015 4 МарголинВ.И., Физические основы микроэлектроники. М.: Академия, 2008. – 400с. 5 ТолмачевВ.В., Скрипник Ф.В. Физические основы электроники. М.: НИЦ «Регулярная и хаотическая динамика», Институт компьютерных исследований, 2009. – 462с. 6 Майер Р.В., Основы электроники. М.: ГГПИ, 2011. – 180с. 7 Прянишников В.А. Электроника. Полный курс лекций. - СПб.: КОРОНА принт, Бином Пресс, 2006, - 416с.
Further reading
- 1 ОпадчийА. Аналоговаяи цифроваяэлектроника. –М.: Горячаялиния. Те-леком, 1999. 2 Ямнурин Н.П.Электроника. –М.: «Академия», 2011, 238. 3 Щука А.А. Электроника.Учебное пособие. Изд-во.:ВНV-СПб, 2005. -800с. 4 БулычевА.Л., Лямин П.М., Тулинов В.Т.Электронные приборы. Учебник для ВУЗов–М.: Лайт, ЛТД 2000. – 416с. 5 Fehr. III, Ralph. Industrial power distribution : train aid / R. E. Fehr. III. - second edition. - Canada : Wiley, 2016. - 411 p. - Index: р. 405-411
