Differential equations
Course: Informatics
Structural unit: Faculty of Computer Science and Cybernetics
Title
Differential equations
Code
ОК.25
Module type
Обов’язкова дисципліна для ОП
Educational cycle
First
Year of study when the component is delivered
2021/2022
Semester/trimester when the component is delivered
3 Semester
Number of ECTS credits allocated
6
Learning outcomes
PLO2. Use modern mathematical apparatus of continuous and discrete analysis, linear algebra, and analytical geometry to solve theoretical and applied problems in the design and implementation of informatization objects. PLO6. Use methods of numerical differentiation and integration, methods of ordinary differential and integral equations solving. Use features of numerical methods and apply them to solving engineering problems. Have skills in the software implementation of numerical methods.
Form of study
Full-time form
Prerequisites and co-requisites
To successfully study the discipline "Differential Equations", a student must meet the following requirements: 1. Successful completion of courses: 1. Mathematical analysis. 2. Algebra and geometry. 2. Knowledge: 1. Theoretical foundations of basic concepts of mathematical analysis, linear algebra, and operations research. 2. Principles of building mathematical models. Formalization of problem statements. 3. Skill: 1. Formulate and solve linear programming problems 2. Solve systems of linear algebraic equations with parameters. 3. Investigate functions at the extremum. 4. Ownership: 1. Basic skills in building, analyzing, and applying mathematical models when solving applied problems. 2. In English at the appropriate level. 3. Use packages of application programs for numerical analysis.
Course content
Familiarization with methods of solving various types of ordinary differential equations (ODEs), equations with partial derivatives, systems of differential equations, setting and solving Cauchy problems, familiarization with methods of modeling dynamic systems and studying their stability, familiarization with the basics of the calculus of variations for solving extreme problems. As a result of studying the academic discipline, the student should know basic concepts and definitions for the integration of scalar DRs and systems of ordinary DRs, linear DRs with partial derivatives, approaches to the analysis of singular points on the plane and the study of the stability of autonomous systems, statements and methods of solving the simplest variational problems. Be able to: solve integrated scalar DRs and systems of ordinary DRs, linear DRs with partial derivatives, conduct research on singular points and qualitative characteristics of constructed mathematical models, analyze stability, asymptotic stability, stability under constant disturbances of autonomous systems, solve the simplest variational problems. On the other hand, based on theoretical explanations, investigate problems that have an applied nature. Special attention is paid to the ability to develop numerical algorithms for stability analysis, obtain optimal estimates, and create software-algorithmic complexes for solving applied problems.
Recommended or required reading and other learning resources/tools
1. Garashchenko F.H., Matviienko V.T., Pichkur V.V., Kharchenko I.I. Dyferentsialni rivniannia, variatsiine chyslennia ta yikh zastosuvannia.. Navch. posib.. – K.: VPTs "Kyivskyi universytet", 2015. – 271 p. 2. Garashchenko F.H., Kharchenko I.I. Zbirnyk zadach i vprav z dyferentsialnykh rivnian. – K.: VPTs "Kyivskyi universytet", 2004. – 162 p. 3. Khusainov D. Ya., Bychkov O.S. Dyferentsialni rivniannia: Navchalnyi posibnyk. – K.: VPTs "Kyivskyi universytet", 2001. – 132 p. 4. Garashchenko F.H., Matviienko V.T., Kharchenko I.I. Dyferentsialni rivniannia dlia informatykiv. Pidruchnyk [z hryfom MON Ukrainy]. –VPTs „Kyivskyi universytet”, K., 2008. – 351 p. 5. Liashko I.I., Boiarchuk O.K, Hai Ya.H., Kalaida O.F. Dyferentsialni rivniannia. – K.: Vyshcha shkola, 1981. – 504 p. 6. Samoilenko A.M., Krivosheya S.A., Perestyuk N.A. Differentsialnie uravneniya. Primeri i zadachi. – K.: Vyshcha shkola, 1984. – 408 p.
Planned learning activities and teaching methods
Lectures, practical classes, independent work.
Assessment methods and criteria
Semester assessment: 1. Control work 1: 25/15 points. 2. Control work 2: 25/15 points. 3. Verbal answers: 10/6 points. Final assessment (in the form of an exam): the maximum number of points that can be obtained by a student: 40 points. Form and types of tasks: written work.
Language of instruction
Ukrainian
Lecturers
This discipline is taught by the following teachers
Ihor
Ivanovych
Kharchenko
Complex systems modelling
Faculty of Computer Science and Cybernetics
Faculty of Computer Science and Cybernetics
Volodymyr
T.
Matvienko
Complex systems modelling
Faculty of Computer Science and Cybernetics
Faculty of Computer Science and Cybernetics
Volodymyr
V.
Pichkur
Complex systems modelling
Faculty of Computer Science and Cybernetics
Faculty of Computer Science and Cybernetics
Yaroslav
P.
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
Complex systems modelling
Faculty of Computer Science and Cybernetics
Complex systems modelling
Faculty of Computer Science and Cybernetics