Laser technology and applied quantum electronics

Course: Laser and optoelectronic technique

Structural unit: Faculty of Physics

Title
Laser technology and applied quantum electronics
Code
ОК3
Module type
Обов’язкова дисципліна для ОП
Educational cycle
Second
Year of study when the component is delivered
2022/2023
Semester/trimester when the component is delivered
1 Semester
Number of ECTS credits allocated
6
Learning outcomes
- Be able to perform analysis engineering products, processes and systems as installed criteria, select and apply the most suitable analytical, computational and experimental research methods, interpret the results Research - Be able to formulate and solve problems in the industry metrology related to surveillance procedures objects, measurement, control, diagnosing and forecasting with given the importance of social Constraints - Analyze and evaluate the impact of information and measurement engineering and metrological activities on the environment and safety of human life - Know and understand the physical basics of device operation and systems based on laser technology and nonlinear optics.
Form of study
Full-time form
Prerequisites and co-requisites
1. Have knowledge of the basic phenomena of physical optics: interference, diffraction, polarization, dispersion, luminescence. 2. Have knowledge of atomic physics, quantum mechanics and electrodynamics: Maxwell and Schrödinger equations, transition probabilities, quantum mechanical oscillator, systematics of energy levels. 3. Have basic knowledge of the special course "Optical Spectroscopy" and have skills in working with basic optical devices: telescope, collimator, interferometer, spectrograph.
Course content
The special course examines the physical processes and methods of creating an inversion active media, the principles of formation of laser radiation in the resonator, the influence of the active medium, resonator and laser mode on the characteristics laser radiation. The curriculum consists of four sections (topics): Topic 1. Principles of optical amplification and generation. Topic 2. Optical resonators. Topic Z. Types of lasers and methods of pumping them. Topic 4. Modes of operation of lasers and laser systems.
Recommended or required reading and other learning resources/tools
Основна (базова): 1. William T. Silfvast. Laser Fundamentals. Sec. edition. Cambridge, 2004, 670p. 2. M. Ccele. Fundamentals of light sources and lasers. Wiley interscience, 2004, 349p. 3. В.И. Григорук, А.П.Коротков, В.В.Хижняк. Лазерна фізика. – К. 1999. 4. В.П.Гаращук. Основи фізики лазерів. – К., В-во «Пульсари», 2012, 342с. 5. В.П.Ящук. Вибрані питання фізики лазерів. -К., 2017, 72с.
Planned learning activities and teaching methods
Teaching methods: lectures, consultations. Assessment methods: modular control works, essays, exam. The final grade is set on the basis of intermediate grades modular control (45%) and exam (55%).
Assessment methods and criteria
Semester assessment: 1. MR1: modular test 1 (6 points - 10 points) and abstract (3 points - 5 points). 2. MR2: modular test 2 (6 points - 10 points) and abstract (3 points - 5) points). 3. MR3: modular test 3 (6 points - 10 points) and abstract (3 points - 5) points). Final assessment in the form of an exam (33 - 55 points).
Language of instruction
Ukrainian

Lecturers

This discipline is taught by the following teachers

Vasyl Pavlovych Yashchuk
Department of Optics
Faculty of Physics

Departments

The following departments are involved in teaching the above discipline

Department of Optics
Faculty of Physics