Optics of anisotropic and guiding structures

Course: Radio Physics and Electronics

Structural unit: Faculty of Radiophysics, Electronics and Computer Systems

Title
Optics of anisotropic and guiding structures
Code
ВК 01.2
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
4
Learning outcomes
As a result of studying the discipline the student should know: basic concepts of optical systems theory, types of equations for different types of optical media, boundary conditions for waves propagating in them, basic types of waves in optical media and fiber structures, their basic properties, Jones Matrix Methods and Mueller for solving polarimetry problems, matrix models of anisotropic structures and media, the main types of electromagnetic waves in an optical medium, including optical anisotropy. Must be able to solve the transfer equation for polarized optical radiation, build models of applied polarization systems and devices, obtain the dielectric permittivity tensor, describe polarization transformations of radiation in anisotropic structures, find the characteristics of natural waves, design and propose different designs of devices ranges and polarization transformations of these waves.
Form of study
Full-time form
Prerequisites and co-requisites
The discipline "Optics of anisotropic and guiding structures" is based on a series of disciplines of professional and practical training, in particular, "Optics", "Mathematical analysis", "Differential equations", "Mechanics", "Mathematical physics", "Oscillations and waves"
Course content
The program of the discipline considers the laws of dispersion and properties of propagation of optical radiation in different types in bulk anisotropic and guide structures, as well as the dispersion of surface and bulk waves in the optical medium and multilayer structures based on them. Wave equations for individual cases of waves are obtained. The methods of designing and creating signal processing devices in the corresponding optical wavelength ranges are analyzed, as well as the specific designs of the respective devices are given.
Recommended or required reading and other learning resources/tools
1. Матвєєв О.М., Механіка і теорія відносності, Київ: Вища школа, 1993. 2. Коваленко В.Ф., Загальна фізика у прикладах, запитаннях і відповідях: Механіка, Київ, ВПЦ «Київський університет», 2011. 3. Хорунжий В.А., Долбня Е.В., Богатов П.Н. Акустоэлектроника, К.: Техніка, 1984. 4. Хорунжий В.А. Процессоры на поверхностных акустических волнах, К.: Технiка, 1990.
Planned learning activities and teaching methods
Lectures, laboratory work, consultations, individual work.
Assessment methods and criteria
- semester evaluation: control is carried out according to the following principle. The academic semester has two content modules: content module 1 (ЗМ1) includes topics 1-4, content module 2 (ЗМ2) includes topics 5-8. After the completion of the relevant topics, two written modular tests are conducted. Writing the 1st and 2nd modular test papers with a score of at least 15 is mandatory for admission to the credit. - final assessment (in the form of credit): the form of credit is written and oral. The assessment consists of 2 questions, each question is evaluated from 0 to 20 points. In total, you can get from 0 to 40 points for the credit. The condition for achieving a positive grade for the discipline is to obtain at least 60 points, while the grade for learning outcomes 2 [skills] and 4 [autonomy and responsibility] cannot be less than 50% of the maximum level (15 and 5 points, respectively), the grade the credit cannot be less than 24 points.
Language of instruction
Ukrainian

Lecturers

This discipline is taught by the following teachers

Yevgen Anatoliyovych Oberemok
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