Methods of artificial intelligence
Course: Applied mathematics
Structural unit: Faculty of Computer Science and Cybernetics
Title
Methods of artificial intelligence
Code
ДВС.3.02.01
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
4 Semester
Number of ECTS credits allocated
3
Learning outcomes
PLO1. Be able to use in-depth professional knowledge and practical skills to optimize the design of models of any complexity, to solve specific problems of designing intelligent information systems of different physical natures.
PLO3. Gaining knowledge for the ability to evaluate existing technologies and based on analysis to form requirements for the development of advanced information technologies
PLO5. Be able to carry out effective communicative activities of the project development team.
PLO8. Communicate effectively on information, ideas, problems, and solutions with professionals and society at large.
PLO10. Be able to build models of physical and production processes, design storage and data space, and knowledge base, using charting techniques and standards for information systems development.
Form of study
Full-time form
Prerequisites and co-requisites
To successfully study the discipline the student must meet the following requirements:
1. Know chapters on mathematical analysis, basics of artificial intelligence, differential equations, methods for optimizing functions, programming theory, mathematical logic, and mathematical statistics.
2. Be able to: formulate and solve problems of linear programming, modeling of dynamic systems, solve systems of linear algebraic equations with parameters, solve differential equations, and investigate functions and functionals to the extreme.
3. Have the skills to build, analyze, and apply mathematical models in solving applied problems.
Course content
The goal of the discipline is for students to master the methods and methods of creating artificial intelligence tools in specialized computer systems, and to obtain information about the basics of artificial intelligence, the basic concepts of pattern recognition systems, and artificial neural networks.
Recommended or required reading and other learning resources/tools
1. Haykin, S. Neural Networks. A Comprehensive Foundation. Second edition. Prentice Hall, New Jersey - (1998).
2. Shatyrko A., Diblik J., Khusainov D., Bashtinec J. Shodimost processov neyrodinamiki v modeli Hopfilda // Naukovo-teoretychniy J. “Shtucniy intelekt”, 2017, № 3-4, C.139-148. ISSN 1561-5359.
3. Khusainov D., Shatyrko A., Puza B., Novotna V., Pylypenko V. Naukovo-teoretychniy J. “Shtucniy intelekt”, 2019’1-2, № 83-84, C. 49-58. ISSN 1561-5359.
Planned learning activities and teaching methods
Lectures, laboratory work, independent work.
Assessment methods and criteria
Semester assessment:
The maximum number of points that can be obtained by a student is 60 points:
Laboratory work: - 40/24 points.
Current evaluation - 20/12 points.
Final assessment in the form of an exam.
Language of instruction
Ukrainian
Lecturers
This discipline is taught by the following teachers
Andriy
V.
Shatyrko
Complex systems modelling
Faculty of Computer Science and Cybernetics
Faculty of Computer Science and Cybernetics
Yaroslav
Pavlovych
Trotsenko
Complex systems modelling
Faculty of Computer Science and Cybernetics
Faculty of Computer Science and Cybernetics
Departments
The following departments are involved in teaching the above discipline
Complex systems modelling
Faculty of Computer Science and Cybernetics
Complex systems modelling
Faculty of Computer Science and Cybernetics