Applied Modelling Techniques for Micro Nano Systems Engineering

Major: Laser and Optoelectronic Engineering
Code of subject: 7.153.01.E.23
Credits: 7.00
Department: Photonics
Lecturer: DScTec., Assoc. prof. Yaremchuk Iryna Yaroslavivna
Semester: 2 семестр
Mode of study: денна
Learning outcomes: • bases of algorithms and their implementation in software packages; • build a mathematical model of the basic physical processes and phenomena in dielectric, magnetic and superconducting and other materials that determine their functionality and operating principles of devices in micro and nanosystemniy technology; • Properties basic materials and micro-electronic technology and optoelectronics, how to control their structure and properties; • basic principles of numerical schemes for solving boundary problems; • modeling algorithms built using application package COMSOL; • have theoretical and practical basics of modeling by finite element technology and devices in micro nanosystemniy technology. Fundamentals of boundary problems for the design and operation of various micro nanosystemnyh devices.
Required prior and related subjects: • prerekvizyt: higher mathematics • korekvizyty: laser technology
Summary of the subject: General principles of mathematical models to describe physical processes and phenomena in dielectric, magnetic and superconducting and other materials that determine their functionality and operating principles of devices in micro and nanosystemniy technology; Theoretical basis of finite element method and implementation of method as the basis for modeling different class boundary problems. We consider the methodology of the solution of the problem of constructing mathematical counterpart, describing the object of research, choice of boundary and initial conditions, to build numerical counterpart in the field of research, calculation and presentation of results in graphical and file type. The objective of the discipline is to get the student practical knowledge in the field of simulation technologies and devices for micro and nanosystemniy.
Assessment methods and criteria: • Current control (30%): written reports on laboratory work, oral examination • Final control (70% differentiated test): Test
Recommended books: 1. Исаченко В.П. Осипова В.А. Сукомел А.С. Теплопередача: Учебник для вузов. – М.: Энергоиздат, 1981. 416 с. 2. Дульнев Г.Н. Парфенов В.Г. Сигалов А.В. Применение ЭВМ для решения задач теплообмена: Учеб. пособие для теплофизич. и теплоэнергетич. спец. вузов. М.: Высш. шк., 1990. 207 с. 3. Абиев Р.Ш. Вычислительная гидродинамика и тепломассообмен. Введение в метод конечных разностей: Учебное пособие. – СПб.: Изд-во НИИХимии СПбГУ, 2002. – 576 с. 4. Сегерлинд Л. Применение метода конечных элементов. – М.: Мир, 1979. – 392 с.