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Solid State Electronics (курсова робота)
Major: Micro and Nanosystems of the Internet of Things
Code of subject: 6.153.03.O.036
Credits: 2.00
Department: Semiconductor Electronics
Lecturer: Dr.Sc., Prof. Anatoli O. Druzhinin
Semester: 6 семестр
Mode of study: денна
Завдання: The study of an educational discipline involves the formation of education seekers competencies:
general competences:
1. Basic knowledge of fundamental sciences, to the extent necessary for mastering general professional disciplines; in the field of micro- and nanosystem engineering, necessary for development professionally oriented disciplines.
2. The ability to solve tasks and make appropriate decisions; ability to
analysis and synthesis, to the application of knowledge in practice;
3. Ability to search and analyze information from various sources; have
research skills; the ability to work both individually and in a team.
professional competences:
1. Basic knowledge of scientific concepts, theories and methods necessary for understanding the principles
operation and functional purpose of micro- and nanosystem devices and devices
techniques; basic knowledge of the main normative legal acts and reference materials,
current standards and technical conditions, instructions and other regulations
documents in the field of "Automation and Instrumentation";
2. the ability to use knowledge and skills for calculation, research, choice,
implementation, repair, and design of micro- and nanosystem devices and devices equipment and their components; the ability to develop methods for assessing the quality of micro- and materials
nanosystem technology, methods of testing devices and devices, metrological systems verifications; the ability to argue the choice of methods for solving specialized problems, critically evaluate the obtained results and defend the decisions made.
Learning outcomes: As a result of the study of the academic discipline, the student of education should be capable
demonstrate the following learning outcomes:
1. Know the main stages of development of solid-state electronics;
2. Know the classification of materials according to their electrical properties;
3. To analyze the electrophysical properties of conductors, semiconductors and
dielectric materials;
4. Analyze physical processes in metals, semiconductors and dielectrics;
5. Know the classification of magnetic materials and their properties.
Required prior and related subjects: Previous academic subjects: Quantum mechanics and statistical physics, Physics of semiconductors and dielectrics, part 1, Quantum electronics and laser machinery
Accompanying and following educational disciplines: Fundamentals of micro- and nanotechnology, Physics of semiconductors and dielectrics, part 2, Microcircuit engineering, part 1,2
Summary of the subject: . Abstract of the academic discipline
In the course work (in the first part), a theoretical analysis of the main physical processes in semiconductor devices and devices of micro-nanosystem technology is carried out.
Mathematical analysis includes principles of operation of semiconductor devices and explanation of physical phenomena, physics of contact phenomena in semiconductors, metal-semiconductor contacts, metal-dielectric-semiconductor structures. Static characteristics and dynamic parameters of bipolar and field-effect transistors are calculated with the help of manuals or reference sheets of technical data (specifications). The second part of the course work involves the study of changes in the parameters and properties of semiconductor devices depending on the operating modes
according to your task option.
Опис: The structure of the educational process for course work
1. Familiarization with the task, methodology completion of coursework and clarification variant of the task.
2. Writing the theoretical section
3 Analysis and calculation of scheme elements
4 Construction of an electrical circuit of a device performing an analog function
5 Protection of course work
Assessment methods and criteria: Methods of knowledge diagnosis
1. Current control in the form of a teacher checking parts of the course work according to the description
stages of course work.
2. Final control in the form of coursework defense.
Критерії оцінювання результатів навчання: . Criteria for evaluating the results of course work
Current control -0,
Checking the text and graphic part of the coursework -40,
Defense of coursework -60.
Recommended books: . Educational and methodological support
1. Druzhinin A.O., Lyakh-Kaguy N.S., Nichkalo S.I. (2019). Calculation and design of semiconductor diodes and transistors as elements of micro- and nanosystem technology: methodical
instructions for completing coursework from the course "Solid-state electronics, part 1" for students of the basic direction 6.050801 "Micro- and nanoelectronics" and specialty 153 "Micro- and
nanosystem technology" - Lviv: Publishing House of Lviv Polytechnic, 2019. - 46 p.
2. Druzhinin A.O., Lyakh-Kaguy N.S., Nichkalo S.I. (2020). Calculation and design of fields transistors as elements of micro- and nanosystem technology: methodical instructions for implementation
coursework from the course "Solid-state electronics, part 1" for students of the basic direction 6.050801 "Micro- and nanoelectronics" and specialties 153 "Micro- and nanosystem engineering" -
Lviv: Publishing House of Lviv Polytechnic, 2020. – 40 p.
3. Druzhinin A.O., Lyakh-Kaguy N.S., Nichkalo S.I. (20017). Laboratory practice with
of solid-state electronics. Part 1: Semiconductor Diodes and Bipolar Transistors:
method. instructions for students of the basic direction 6.050801 "Micro- and nanoelectronics" and
specialty 153 "Micro- and nanosystem technology" / author: A.O. Druzhinin, N.S. Lyakh-Kaguy,
SI. Nichkalo.– Lviv: Publishing House of Lviv Polytechnic, 2017.– 64 p.
4. Druzhinin A.O., Nichkalo S.I., Lyakh-Kaguy N.S. (2018). Laboratory practice on solid state
electronics Part 2: Thyristors. Field-effect transistors: method. instructions for students
basic direction 6.050801 "Micro- and nanoelectronics" and specialty 153 "Micro- and
nanosystem technology" / editor: A.O. Druzhinin, S.I. Nichkalo, N.S. Lyakh-Kaguy. – Lviv:
Lviv Polytechnic Publishing House, 2018. – 48 p.
Recommended literature
Basic
1. Druzhinin A.O., Lyakh-Kaguy N.S., Nichkalo S.I. Solid-state electronics. Part 2: electronic
educational and methodical complex. – registration number No. E41-124-96/2021 dated 05/13/2021 –
Certificate No. 03993. hosting address: http://vns.lpnu.ua/course/view.php?id=6000
2. Druzhynin A.O., Lyakh-Kaguy N.S. Solid-state electronics. Part 1: electronic educational
methodological complex. – registration number No. E41-124-24/2015 dated 06.16.2015 – address
location: http://vns.lp.edu.ua/course/view.php?id=13009
3. Druzhinin, A. O. (2009). Solid-state electronics. Physical foundations and properties
semiconductor devices. Lviv: Publishing House of the National University of Lviv
polytechnic - 332 p.
4. Druzhinin A.O., Ostrovsky I.P., Khoverko Y.M., Nichkalo S.I. (2013). Devices on the basis
MES-structures in micro- and nanoelectronics: a synopsis of lectures for masters and specialists
specialty 7.05080101 (8.05080101) "Micro- and nanoelectronic devices and devices". –
Lviv: Lviv Polytechnic Publishing House. - 68 p.
Auxiliary
1. Borisov, O. V. (2006). Fundamentals of solid-state electronics. Semiconductor diodes / Borisov OV, Gusev VO, Rodionov MK–K.: NTUU "KPI. -212 p.
2. Borysenko, O. A., Kobyakov, O. M., Novgorodtsev, A. I., Kulyk, I. A., Onanchenko, E. L., & Lopatchenko, B. K. (2013). Solid-state electronics.
3. Kobyakov, O. M., Opanasyuk, A. S., Brazhnyk, I. E., & Lyubiviy, O. A. (2015). Solid state electronics. Microcircuitry.
4. Borysov, O. V., Volkhova, T. L., & Korolevych, L. M. (2018). Solid-state electronics:
practicum
9. Information resources
http://vns.lpnu.ua/course/view.php?id=6000
http://vns.lp.edu.ua/course/view.php?id=13009
http://essuir.sumdu.edu.ua/handle/123456789/38908
http://essuir.sumdu.edu.ua/handle/123456789/38908
https://ela.kpi.ua/bitstream/123456789/24896/1/tverdotilna_elektronika.pdf