We use cookies.
By using the site, you agree to our Privacy Policy.

Contract number
075-15-2019-1931
075-15-2022-1101
Time span of the project
2019-2023
Invited researcher
since August 2023 Pochinka Olga Vitalievna

As of 01.12.2023

48
Number of staff members
37
scientific publications
General information

Name of the project: Dynamic systems theory and its applications

Goals and objectives

Project objective: Development of dynamic systems and differential equation theory, research of problems of stratification theory and group theory related to this theory, as well as numerical modeling and analytical research of systems with applications to physics, geophysics and engineering.

The practical value of the study

Scientific results:

The main goal of the project is to create new methods of research of systems with a nontrivial dynamics. The chaotic behavior of solutions of smooth differential equations was discovered already in the late 19th century; efforts of many outstanding mathematicians and physicists of the past were devoted to  the research of this phenomenon. As of today, the theory of dynamic  systems, thanks to its interdisciplinary nature (from the mathematical standpoint it is at the same time a domain of analysis, a part of geometry and a branch of the group theory and, simultaneously, probability theory, with applications to number theory etc.) is one of the most steadily developing domains of mathematics. The number of applied problems in which dynamic chaos can be observed is vast and the question of statistical properties of multidimensional systems with chaotic dynamics is one of the fundamental problems of physics. Nevertheless, the modern state of the theory does not give almost any mathematically strictly substantiated information on the structure of the chaotic dynamic in practically any randomly selected physical system. The cause is the focus of the majority of researchers on systems that possess some «convenient» mathematical structure (one or another variety of hyperbolicity, symmetry etc.), which leads to description of only specifically prepared examples or only unstable dynamic modes. This project, to the contrary, is aimed at researching mathematical structures that formalize the main persistent properties of the dynamics of systems of natural origin in the most adequate way, as well as at creating and strictly substantiating corresponding methods for studying dynamic chaos found in applied problems.

In the theory of systems on manifolds and the theory of strange attractors, the following results have been achieved:

  • we researched flows that satisfy Smale's axiom A on an arbitrarily oriented 3-manifold. It has been demonstrated that two-dimensional basic sets of such flows are either hyperbolic attractors or hyperbolic repellers;
  • a complete description has been provided for the structure of the basins of attraction of such attractors;
  • a complete description has been provided for the topological structure of orientable 2-manifolds that allow А-diffeomorphisms with a specified number of one-dimensional basic sets;
  • we have provided an exhaustive topological classification of non-singular Morse–Smale flows with two periodical trajectories of manifolds of arbitrary dimensionality;
  • it has been demonstrated that for manifolds that allow such flows there exist from one to three classes of topological equivalence of such flows, depending on the type of the manifold;
  • we obtained a classification of Morse–Smale diffeomorphisms of 2-manifold with respect to stable isotopism in the Newhouse–Palis–Takens sense.

In the theory of bifurcations, holomorphic dynamics and the theory of reversible systems:

  • our researchers have proposed a scenario that allows to arbitrarily change  the homotopy type of a closure of an unstable manifold of a saddle periodic point for polar diffeomorphisms of a two-dimensional torus;
  • we have studied the structure of the closure of the set of critical points of multipliers of a family of quadratic maps of the complex plane;
  • our researchers have studied reversible non-conservative perturbations of cubic Hénon map. In particular, we researched rearrangements related to 1:3 resonance. It was demonstrated that the destruction of this resonance leads to bifurcations of symmetry destruction and to the birth of a new mixed dynamic (intersection of the attractor and the repeller) due to the formation of nontrivial heteroclinic cycles. The results were generalized to the case of resonances of arbitrary odd order.

In the domain of applications to problems of mathematical physics:

  • our researchers have obtained universal topological ratio between the number of null points and magnetic field points for branching configurations of separators connecting sources and null pints that are responsible for the structure of anemone-like Solar flare;
  • we have studied rearrangements of sine waves in modified Korteweg–De Vries equations with third- and fifth-order nonlinearities. In the limit of null dispersion we provided analytical expressions for the time and level of wave breaking. We provided a description of the main laws of inelastic interaction of soliton-like solutions. The dynamics of a gas of interacting breathers has been studied, including irregular waves and turbulence, as well as the statistical properties of obtained wave solutions. We found waves of extreme amplitude;
  • our researchers have proposed an efficient procedure for reconstructing the phase of an oscillator system by iterative application of Hilbert transform. We demonstrated that this method significantly improves the quality of reconstruction for high-frequency oscillations. 

Implementation of research results:

As part of the project, we have developed a software complex that implements high-performance methods of numerical research of multidimensional dynamic systems. Using the developed complex, we have obtained the following results of our research of applied models: in the field of models of the dynamics of encapsulated gas bubbles in fluid we found regions with hyperchaotic oscillations of bubbles, established the possibility of transfer from synchronous oscillations to asynchronous ones, it was shown that this process is performed according to the bubble transition scenario; in the area of dynamic systems modeling the functioning of gene networks we have described the mechanisms of transition from regular periodic modes corresponding to in-phase and anti-phase modes of activity, to chaotic ones; in the domain of ensembles of interacting neuron-like elements with topology of connection changing over time we have found and described a new effect, when periodic opening and closing of the link between the elements of the ensemble leads to an exponential growth of energy; in hydrodynamic models describing convection in a layer of liquid we determined the existence of pseudo-hyperbolic attractors, as well as quasi-attractors existing on sets of values of parameters that have a positive Lebesgue measure. 

Organizational and infrastructural changes:

We have created a center for the collective use of scientific equipment that features a heterogeneous computing device. On this facility we deployed the developed software complex, which can be accessed via the local network. Users of the complex have the ability to research model problems, allowing to enhance the understanding of various dynamic phenomena and to create and research their own problems described with finite-dimensional dynamic systems. 

Education and personnel occupational retraining:

We have developed and implemented the lecture courses «Dynamics of endomorphisms», «Modern theory of dynamic chaos», «Theory of bifurcations of multidimensional diffeomorphisms», «Quantum mechanics for mathematicians», «Applied theory of dynamic systems», «Introduction to one-parameter semigroups of operators and linear evolution equations», «Dynamic systems and applications», «Additional chapters of the qualitative theory of dynamic systems, geometry and real analysis», «Foundations of the theory of oscillations». «Fluctuations in physical systems».

In 2021–2022, under the supervision of the leading scientist six employees of the Laboratory completed internships at a laboratory at Imperial College London (United Kingdom) on the topic of the project. In 2023, an internship of 2 members of the laboratory's scientific team was held at the Regional Scientific and Educational Mathematical Center "Mathematics of Future Technologies" on the basis of Nizhny Novgorod Lobachevsky University.

We have conducted international schools and conferences:

  • International student school and conference «Mathematical spring 2020» 17–21 February 2020
  • International student school and conference «Mathematical spring 2021» 30 March–1 April 2021
  • International student school and conference «Mathematical spring 2023» 27 March–30 March 2023

Cooperation:

  • School of Mathematical Sciences, Tongji University, China
  • Research Institute of Cardiology of Saratov State Medical University named after V.I. Razumovsky
  • Scientific and educational laboratory "Nonlinear analysis and design of new vehicles" of Udmurt State University.

Hide Show full
Nozdrinova E.V., Pochinka O.V.
«On the solution of the 33rd Palis-Pugh problem for gradient-like diffeomorphisms of a 2-sphere», RUSSIAN MATHEMATICAL SURVEYS , 2020.04 (Том: ‏ 75 Выпуск: ‏ 2 Стр.: ‏ 383-385)
Chigarev Vladimir, Kazakov Alexey, Pikovsky Arkady
«Kantorovich-Rubinstein-Wasserstein distance between overlapping attractor and repeller», CHAOS, 2020.07 (Том: ‏ 30 Выпуск: ‏ 7).
Kulagin N., Lerman L., Malkin A.
«Solitons and cavitons in a nonlocal Whitham equation», COMMUNICATIONS IN NONLINEAR SCIENCE AND NUMERICAL SIMULATION , 2021.02 (Том: ‏ 93 Номер статьи: 105525).
Medvedev Timur V., Pochinka Olga V., Zinina Svetlana Kh.
«On existence of Morse energy function for topological flows», ADVANCES IN MATHEMATICS , 2021.02 (Том: ‏ 378 Номер статьи: 107518)
Gonchenko S., Gonchenko S.V. and Turaev D.
«Doubling of invariant curves and chaos in three-dimensional diffeomorphisms», 2021.11 ((Том 31, выпуск 11)
Kurkina O. and Pelinovsky E.
«Nonlinear Transformation of Sine Wave within the Framework of Symmetric (2+4) KdV Equation» SYMMETRY-BASEL, 2022.04 (14 (4)).
Rybkin A., Pelinovsky E., Palmer N.
Inverse problem for the nonlinear long wave runup on a plane sloping beach // Applied Mathematics Letters. 2023. Vol. 145. Article 108786.
Other laboratories and scientists
Hosting organization
Field of studies
City
Invited researcher
Time span of the project
Laboratory «Probability techniques in analysis» (10)

Saint Petersburg State University - (SPbU)

Maths

St. Petersburg

Hedenmalm Haakan Per

Sweden

2024-2028

Laboratory «Nonlinear and nonlocal equations and their applications»

Peoples' Friendship University of Russia - (RUDN University)

Maths

Moscow

Kuksin Sergei Borisovich

Russia, France

2022-2024

Probabilistic Methods in Analysis

Saint Petersburg State University - (SPbU)

Maths

St. Petersburg

Hedenmalm Haakan Per

Sweden

2021-2023