2019/2020
Научно-исследовательский семинар "Дискретные интегрируемые уравнения и их редукции"
Лучший по критерию «Полезность курса для Вашей будущей карьеры»
Лучший по критерию «Полезность курса для расширения кругозора и разностороннего развития»
Лучший по критерию «Новизна полученных знаний»
Статус:
Дисциплина общефакультетского пула
Кто читает:
Факультет математики
Где читается:
Факультет математики
Когда читается:
1, 2 модуль
Преподаватели:
Погребков Андрей Константинович
Язык:
английский
Кредиты:
3
Контактные часы:
30
Course Syllabus
Abstract
Creation and development of the theory of integrable equations is one of main achievements of the mathematical physics of the fall of the previous century. Ideas and results of this theory penetrate in many branches of the modern mathematics: from string theory to the theory of Riemann surfaces. Nowdays essential attention is attracted to the theory of discrete integrable equations. In this lectures a generic approach to construction and investigation of such equations will be presented.
Learning Objectives
- Students will gain an understanding of the main ideas of integrability for difference equations and their consequences.
Expected Learning Outcomes
- Students will be able to construct integrable equations, their Lax pairs
- Students will be able to investigate properties of solutions of integrable difference equations and their reductions
Course Contents
- Commutator identities on associative algebras
- DBAR-problem and dressing operators
- Dressing and Lax pairs
- Hirota difference equation (HDE)
- Higher analogs of HDE
- Direct and the Inverse scattering transform for the HDE
- Soliton solutions
- Two-dimensional reductions, their integrability
- Dispersion relation and integrals of motion
- Other hierarchies of the discrete integrable equations
Assessment Elements
- cumulative gradeThe cumulative grade is proportional to the number of problems solved so that 10 corresponds to 75% of all problems + bonuses for active participants.
- Final examOral exam. Unless stated otherwise, all grades are rounded to the nearest integer (half-integers are rounded upwards
Bibliography
Recommended Core Bibliography
- Pogrebkov, A. (2016). Commutator identities on associative algebras, the non-Abelian Hirota difference equation and its reductions. Theoretical & Mathematical Physics, 187(3), 823–834. https://doi.org/10.1134/S0040577916060039
Recommended Additional Bibliography
- Hirota Difference Equation and Darboux System: Mutual Symmetry. (2019). Retrieved from http://search.ebscohost.com/login.aspx?direct=true&site=eds-live&db=edsbas&AN=edsbas.F587178B