Functional optoelectronics

Course: Applied Physics and Nanomaterials

Structural unit: Faculty of Radiophysics, Electronics and Computer Systems

Title
Functional optoelectronics
Code
ВБ 1.7
Module type
Вибіркова дисципліна для ОП
Educational cycle
Second
Year of study when the component is delivered
2023/2024
Semester/trimester when the component is delivered
2 Semester
Number of ECTS credits allocated
3
Learning outcomes
1. Know the types, parameters and characteristics of the main devices of function-al optoelectronics 2. To know methods of mathematical processing of optical signals, methods of modu-lation and scanning of an optical signal 3. Know the physics of light propagation through an optical fiber, types and meth-ods of manufacturing optical fibers, the principle of designing fiber-optic in-formation transmission systems 4. Know the basics of analog, digital and hybrid optical processors 5. Understand the basics of operation and the component base of optoelectronic pattern recognition systems
Form of study
Full-time form
Prerequisites and co-requisites
Student should know: basic laws, equations and relationships of electricity and magnetism, atomic physics, statistical physics, quantum mechanics and relevant sections of the theory of differential equations and probability Student must be able to: set physical problems, identify practically expedient approaches to their solution and to use mathematical methods necessary in each specific case.
Course content
The study of the discipline "Nuclear Physics and Astrophysics" makes it possible to understand the essence of such phenomena, technologies and problems: 1) methods of analyzing processes in nu-clear and mixed atomic-nuclear systems based on atoms and molecules; 2) transformation of the physical properties of matter in the range from quarks, nucleons, nuclei, atoms, and molecules to large and superlarge ensembles in the form of plasma, gas, and solids; 3) mechanisms of nuclear fission and fusion reactions; 4) principles of operation and main types of nuclear reactor designs; 5) nuclear fusion implementation mechanisms and systems; 6) the foundations of cosmology, starting with the Big Bang and up to the present time; 7) ways of formation and evolution of stars of different masses; 8) basic concepts of dosimetry and radiation safety.
Recommended or required reading and other learning resources/tools
2. Noboru Takigawa& Kouhei Washiyama, Fundamentals of nuclear physics, Springer, 277 p., 3. Nuclear Physics: Exploring the Heart of Matter, The National Academies Press, Washington D.C., 2013, 277 p., 4. Висоцький В.І., Дяченко С.А., Карлаш Г.Ю., Овечко В.С., Прокопенко О.В., Харченко Н.П. Атомна та ядерна фізика в прикладах і запитаннях, Учбовий посібник (за ред. В. І. Висоцького, В. С. Овечка). ВПЦ "Київський університет", 2011, 511 с. 5. С.М. Андрієвський, С.Г. Кузьменков, Ядерна астрофізика, Одеса, ОНУ, 2022, 119 с.,
Planned learning activities and teaching methods
Teaching takes place in the form of lectures and practical classes, during the semester a colloquium (oral form) and a modular control work are planned.
Assessment methods and criteria
The academic semester divides on two substantive modules: oral modular colloquium and modular control work are held. The exam is carried out in a combined written and oral mode. The examina-tion ticket consists of 2 questions, the questions are evaluated for 20 points. The condition for achieving a positive grade for the discipline is to obtain at least 60 points, the grade for the exam cannot be less than 24 points.
Language of instruction
Ukrainian

Lecturers

This discipline is taught by the following teachers

Hanna Yuriivna Karlash
Department of Quantum Radio Physics and Nanoelectronics
Faculty of Radiophysics, Electronics and Computer Systems

Departments

The following departments are involved in teaching the above discipline

Department of Quantum Radio Physics and Nanoelectronics
Faculty of Radiophysics, Electronics and Computer Systems