Nonclassical problems of mathematical physics
Course: Applied mathematics
Structural unit: Faculty of Computer Science and Cybernetics
Title
Nonclassical problems of mathematical physics
Code
Module type
Обов’язкова дисципліна для ОП
Educational cycle
Second
Year of study when the component is delivered
2021/2022
Semester/trimester when the component is delivered
4 Semester
Number of ECTS credits allocated
5
Learning outcomes
PLO1. Be able to use of 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 nature.
PLO10. Be able to build models of physical and production processes, design of storage and data space, knowledge base, using charting techniques and standards for information systems development.
Form of study
Prerequisites and co-requisites
To successfully learn the discipline “Nonclassical problems of mathematical physics” the student should satisfy the following requirements.
They have successfully passed the courses Calculus, Functional Analysis, and Equations of Mathematical Physics.
They know (a) fundamentals of Calculus, Functional Analysis, and Equations of Mathematical Physics.
They can (a) apply fundamentals of Calculus, Functional Analysis, and Equations of Mathematical Physics to solve practical problems.
They should be able to (a) seek information in the Internet.
Course content
Block 1. Fundamentals
Distributions
Rigged Hilbert spaces
Sobolev spaces
Weak solutions of initial-boundary problems
Galerkin method and its analogues
Optimal control and system controllability
Control work
Block 2. Nonclassical problems
Weak solvability of pseudoparabolic systems
Galerkin methods analogues for pseudoparabolic systems
Pulse optimal control of pseudoparabolic systems
Weak solvability of pseudohyperbolic systems
Galerkin method analogues for pseudohyperbolic systems
Pulse optimal control of pseudohyperbolic systems
Weak solvability of Sobolebʼs systems
Galerkin method analogues for Sobolevʼs systems
Pulse optimal control of Sobolevʼs systems
Barenblatt–Zheltov–Kochina model
Control work
Recommended or required reading and other learning resources/tools
1. Lyashko S.I. Obobschennoe upravlenie lineynyimi sistemami. K.: Nauk. dumka, 1998.
2. Vragov, V.N. Kraevyie zadachi dlya neklassicheskih uravneniy matematicheskoy fiziki. Novosibirsk: NGU, 1983.
3. Vladimirov V.S. Uravneniya matematicheskoy fiziki. M.: Nauka, 1981.
4. Korpusov M.O., Sveshnikov A.G. Nelineynyiy funktsionalnyiy analiz i matematicheskoe modelirovanie v fizike. M.: Krasand, 2011.
5. Sveshnikov A.G, Alshin A.B., Korpusov M.O., Pletner Yu.B. Lineynyie i nelineynyie uravneniya sobolevskogo tipa. M.: Fizmatlit, 2007.
Planned learning activities and teaching methods
Lectures, independent work, recommended literature processing, homework.
Assessment methods and criteria
Intermediate assessment:
The maximal number of available points is 60.
Test work no. 1: RN 1.1, RN 1.2 – 30/18 points.
Test work no. 2: RN 1.1, RN 1.2 – 30/18 points.
Final assessment (in the form of final test):
The maximal number of available points is 40.
The results of study to be assessed are RN 1.1, RN 1.2, RN 2.1, and RN 3.1.
The form of final test: writing.
The types of assignments are 3 writing assignments (2 theoretical and 1 practical).
Language of instruction
Ukrainian
Lecturers
This discipline is taught by the following teachers
Departments
The following departments are involved in teaching the above discipline