Microprocessor technology in high energy physics
Course: High Energy Physics
Structural unit: Faculty of Physics
Title
Microprocessor technology in high energy physics
Code
ВБ 4.3
Module type
Вибіркова дисципліна для ОП
Educational cycle
Second
Year of study when the component is delivered
2018/2019
Semester/trimester when the component is delivered
3 Semester
Number of ECTS credits allocated
6
Learning outcomes
1.1 Know the principles of digital signal processing and the use of digital signal processors in spectrometers of nuclear radiation, including on the basis of PLM
2.1 Be able to perform theoretical analysis and optimization of spectrometric paths;
Practically study the operation of analog and digital spectrometers;
Perform simulation of digital devices
Form of study
Full-time form
Prerequisites and co-requisites
- Successful learning of the basic physics courses: "Mechanics", "Molecular physics", "Electricity", "Optics".
-To be able to solve problems in the main physics courses.
-Have the elementary skills of working on a computer to search for information on the Internet.
-The student must know the basics of analogue and digital spectrometric circuits.
-Understand the principles of operation of logical elements and functional devices of computing technology;
-Knowledge the structure and operating principles of integrated microprocessors;
-Understand the functional features and structure of nuclear physical interfaces of measuring systems.
Course content
The course "Microprocessor Technology in High Energy Physics" will significantly improve the professional training of the students of the Department of Nuclear Physics, which is due to the fact that the students will:
- be aware of the principles of digital signal processing and the use of digital signal processors in nuclear imaging spectrometers, including those based on PLM.
- be able to carry out theoretical analysis and optimisation of spectrometric circuits;
- To inspect practically the functioning of analogue and digital spectrometers;
- Perform modelling of digital devices.
Recommended or required reading and other learning resources/tools
[1] Nikityuk N.M. Microprocessors and microcomputers: application in instrument making and scientific research., 1981.
[2] Stupin Yu.V., Methods of automation of physical experiments and installations based on computers, 1983.
[3] Finogenov KG, Programming of real-time measuring systems. 1990.
[4] Tretyak O.V., Boyko Yu.V., Zasoby ta sistemy avtomatizatsii naukovykh doslijen., VPC "Kyiv University", 2003.
[5] Microprocessor technology: Pidruchnik / Yu.I. Yakimenko, T.O. Tereshchenko, E.I. Sokol, V.Ya. Zhuikov, Yu.S. Peterger / For red. THEN. Tereshchenko. - K .: Vidavnitstvo "Polytekhnik", 2002. - 439 p.
Planned learning activities and teaching methods
Lecture demonstration; practical exercises, self-study; counselling
Assessment methods and criteria
- semester assessment:
1. the assessment during the lectures (maximum 50 points).
2. Practical tasks (maximum 50 points).
-Result evaluation in the form of an examination
Language of instruction
Ukrainian
Lecturers
This discipline is taught by the following teachers
Ruslan
Viktorovich
Yermolenko
Department of Nuclear Physics and High Energies
Faculty of Physics
Faculty of Physics
Departments
The following departments are involved in teaching the above discipline
Department of Nuclear Physics and High Energies
Faculty of Physics