
- EDITOR-IN-CHIEF
- Honorary Editor
- Editorial board
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- Passed away
Call for papers
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Special Issue dedicated to the 100th anniversary of the birth of
The deadline for manuscript submissions is July 15, 2026. The issue is provisionally scheduled for publication in November 2026. |
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Maslennikov O. V., Shchapin D. S., Nekorkin V. I.
Abstract
The spatiotemporal dynamics of coupled nonlinear oscillators provide a natural substrate
for the high-dimensional feature transformations required for complex pattern classification. We
investigate this principle using an electronically implemented chain of FitzHugh – Nagumo neurons
operating in the excitable regime. Static two-dimensional inputs are encoded by boundary
pulse-train frequencies applied at the terminal nodes, driving the chain into reproducible,
input-dependent voltage patterns distributed across space and time. We formalize this device
as a physical kernel: a deterministic mapping from a low-dimensional input space to an explicit
feature space derived from measured dynamics. To characterize the resulting kernel beyond accuracy
alone, we introduce kernel tomography diagnostics based on the spectrum of the centered
Gram matrix, including effective dimension and centered kernel alignment, and we benchmark
against standard software classifiers defined directly on the input coordinates. Using controlled
synthetic tasks with increasingly complex decision boundaries, we show that the physical-kernel
representation supports strong performance with simple convex readouts and benefits from a hierarchical
design that combines local spectral features with coupling-aware observables such as
internodal coherence. Furthermore, a lightweight readout incorporating quadratic feature interactions
significantly improves performance by capturing mode interactions while retaining
convex training. Finally, we demonstrate cross-task reuse of a single precomputed response map
by applying nearest-grid lookup to a real vowel formant dataset, achieving nontrivial separability
without any hardware retuning. Overall, the proposed framework provides mechanistic
insight into how forced excitable chains induce task-relevant feature geometry and offers principled
guidance for designing and evaluating neuromorphic hardware as physical kernels for static
classification.
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Markeev A. P., Churkina T. E.
Abstract
The planar restricted problem of three bodies moving under gravitational attraction is considered.
The motions close to the Lagrange libration points are studied. The orbital eccentricity
of the smaller of the two main attracting bodies and their mass ratio are chosen as problem
parameters. A linear canonical transformation that is $2\pi$-periodic in true anomaly is obtained
analytically up to the 4th degree of eccentricity inclusive, which reduces the Hamiltonian function
of the linearized equations of perturbed motion to a real normal form corresponding to two
harmonic oscillators independent of each other. The oscillations frequencies and the coefficients
in the transformation are obtained explicitly in terms of the problem parameters.
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Vetchanin E. V., Mokrushina L. N.
Abstract
The motion of $N$ point sources on a plane is considered. Equations of motion of this
system are represented in Hamiltonian form with a Hamiltonian that is a multivalued function
of coordinates. A detailed analysis is presented for the case of sources with zero total strength,
where a reduction by two degrees of freedom is possible. For three sources of which two have
identical strengths, an explicit solution to the reduced system (with one degree of freedom) is
constructed. The trajectories of the reduced system always remain on the same single-valued
branch of the Hamiltonian and arrive in finite time at a branching point of the Hamiltonian.
This point corresponds to collision of two sources with strengths of opposite signs. An exception
is the trajectories lying on an invariant manifold which contains a fixed point of the reduced
system. This fixed point corresponds to an equilateral triangular configuration. For four sources
of which two have identical positive strengths and the other two have identical negative strengths,
a reduced system with two degrees of freedom is presented. It is shown that the reduced system
admits three invariant manifolds, on which the motion is integrable. On the two manifolds the
sources form a collinear configuration, and on the third manifold the sources are located at the
vertices of a (convex or concave) deltoid. For the reduced system restricted to the invariant
manifold we have constructed first integrals, phase portraits, and have identified singularities
and fixed points.
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Gonchenko A. S., Gonchenko S. V., Trifonov K. N.
Abstract
We consider two-parameter families of three-dimensional systems, which are normal forms
for bifurcations of an equilibrium state with three zero eigenvalues in the class of systems that
are time-reversible and axially symmetric. We identify those normal forms in which bifurcations
can be observed, leading to the emergence of symmetrical “Lorenz attractor – Lorenz repeller”
pairs. We illustrate only four examples of such normal forms in which we describe bifurcation
scenarios leading to the emergence of different types of such pairs.
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Morozov A. D., Morozov K. E.
Abstract
The paper presents a brief review of results on the theory of nonlinear resonance in systems
with $\frac{3}{2}$ degrees of freedom. We discuss the averaged systems near resonance levels, distinguish
nondegenerate and degenerate resonances, and describe typical phase portraits of the corresponding
first- and second-approximation systems. Conditions for the existence of resonant periodic
solutions are formulated, and the appearance of invariant two-dimensional tori is discussed. Special
attention is paid to resonance zones near degenerate energy levels. Two illustrative examples
are presented, including the occurrence of a degenerate resonance inside a nondegenerate resonance
zone and the appearance of vortex pairs in the Poincaré map. The authors dedicate the
article to V.S. Afraimovich, an outstanding specialist in dynamical systems, on the occasion of
his 80th birthday.
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Kashchenko S. A.
Abstract
We consider the local dynamics (in a neighborhood of the equilibrium state) of nonperiodic
chains of $N$ identical elements, each described by a second-order equation. It is assumed that
the coupling between chain elements is one-sided. The main assumption is that the number $N$
of elements is sufficiently large, i. e., the small parameter is $N^{−1}$. Critical cases in the stability
problem for the zero solution are identified, and it is shown that they have infinite dimension in
the sense that infinitely many roots of the corresponding characteristic equation tend to zero as
the small parameter $N^{−1}$ tends to zero. Known methods of local analysis based on the use of the
method of invariant manifolds and the method of normal forms are not directly applicable in the
problems under consideration. The main results consist in constructing so-called quasinormal
forms — families of special nonlinear boundary value problems of parabolic type, which play
the role of classical normal forms. Bifurcation phenomena are investigated and asymptotics
of families of solutions bifurcating from the equilibrium state are constructed. The coupling
parameter between chain elements and the parameter appearing in the boundary condition turn
out to be fundamentally important. It is shown that the structure of solutions for nonperiodic
chains is generally more complex than for periodic ones (ring chains).
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Kuptsov P. V.
Abstract
While a previously proposed method for estimating inertial manifold dimension, based on explicitly
computing angles between pairs of covariant Lyapunov vectors (CLVs), employs efficient
algorithms, it remains computationally demanding due to its substantial resource requirements.
In this work, we introduce an improved method to determine this dimension by analyzing the
angles between tangent subspaces spanned by the CLVs. This approach builds upon a fast numerical
technique for assessing chaotic dynamics hyperbolicity. Crucially, the proposed method
requires significantly less computational effort and minimizes memory usage by eliminating the
need for explicit CLV computation. We test our method on two canonical systems: the complex
Ginzburg – Landau equation and a diffusively coupled chain of Lorenz oscillators. For the former,
the results confirm the accuracy of the new approach by matching prior dimension estimates.
For the latter, the analysis demonstrates the absence of a low-dimensional inertial manifold,
highlighting a complex regime that merits further investigation. The presented method offers
a practical and efficient tool for characterizing attractors in infinite-dimensional dynamical systems.
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Medvedev V. S., Zhirov A. Y., Zhuzhoma E. V.
Abstract
On a closed orientable surface, we consider the set of axiom A diffeomorphisms whose
nonwandering sets consist of connected one-dimensional expanding attractors and contracting
repellers (any attractor/repeller is locally homeomorphic to the product of segment and Cantor
set). This set consists of $\Omega$-stable diffeomorphisms and structurally unstable diffeomorphisms.
We classify such diffeomorphisms up to the global conjugacy on its nonwandering sets.
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Medvedev A. A., Zhirov A. Y.
Abstract
In this paper, we prove the nonexistence of a generalized pseudo-Anosov homeomorphism on
a closed nonorientable surface of genus 3 whose invariant foliations have two singularities, one of
which has valency 1 and the other has valency 5. The proof essentially uses the construction of
the so-called band surface of a generalized pseudo-Anosov homeomorphism for which a number
of conditions imposed on the structure of its boundary are formulated. The considered set of
singularities is not the only admitted by the Euler – Poincaré formula for genus 3 and the number
of valency 1 singularities being equal to 1. Thus, the statement which we prove provides a case
demonstrating difference from orientable surfaces on which there is a generalized pseudo-Anosov
homeomorphism with any admitted set of singularities if at least one of them is of valency 1,
except for the case of torus for which any sets of singularities with a single singularity of valency 1
are impossible.
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Pochinka O. V., Shmukler V. I., Yakovlev E. I.
Abstract
Every discrete dynamical system (cascade) generated by a homeomorphism induces a continuous
dynamic system (flow) — a suspension. However, not every flow is equivalent to a suspension
over a cascade, a necessary and sufficient condition for this is the existence of a global
section for the flow. In the case of the existence, the flow is equivalent to a suspension over
a Poincaré map on the global section. The basis of the topological dynamics is the topological
classification of cascades (flows) up to a conjugacy (equivalence) realized by a homeomorphism
that sends the trajectories of one system into the trajectories of another while preserving the
direction of the motion. The paper explores the deep relationship between a homeomorphism
and its suspension. The core question is: if two of such suspensions are topologically equivalent,
does it mean the original homeomorphisms were topologically conjugate? Usually, the answer
is “no”, and here a natural question arises about the relationship between the invariants of the
topological conjugacy and the topological equivalence of suspensions for homologically reducible
homeomorphisms. In this paper we identify the exact boundary where the answer becomes “yes”.
We find conditions under which the topological conjugacy of the homeomorphisms on manifolds
is tantamount to the equivalence of the suspensions over them. The found condition, called
homological irreducibility, consists of the absence of the eigenvalue 1 in the first homology group
action. It allows us to distinguish some classes of homologically irreducible homeomorphisms. In
particular, to give an exhaustive description of them in the class of homeomorphisms of surfaces
with nonnegative Euler characteristic.
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Efremova L. S.
Abstract
This work is devoted to the description of some set in the space of $C^1$-smooth skew products of circle maps that have a $3D$-torus as phase space and possess periodic points. This set of maps consists of skew products with an $\Omega$-stable quotient, continuous itinerary auxiliary multifunctions and contains, in particular, an open, but not dense (in the distinguished set) subset of $\Omega$-stable maps (with respect to $C^1$-smooth perturbations of skew products class).
We also select here the other set of $C^1$-smooth skew products of circle maps such that $C^1$-smooth $\Omega$-stable skew products form an everywhere dense subset of this set.
Much attention is paid to maps of the second selected set admitting a maximal ``prickly'' attractor, which is presented as the union of a $2D$-torus with a family of arcs of various lengths, orthogonal to the above $2D$-torus and originating from points of an everywhere dense set of continuum cardinality on this $2D$-torus.
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Gurevich E. Y., Imaev R. R.
Abstract
We show that, for Morse – Smale diffemorphism $f\colon M^n\to M^n$, $n\geqslant 4$, the closure of one- and $(n-1)$-dimensional separatrices in a basin of a sink point $\omega$ forms a trivial frame that contrasts with the case $n=3$. This result is a first step in the solution of problems of topological classification, embedding in a flow and existence of energy functions for such diffeomorphisms.
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Kholostova O. V.
Abstract
The motion of a dynamically symmetric satellite (rigid body) relative to its center of mass
in a central Newtonian gravitational field in a weakly elliptical orbit is considered. The motion
occurs in the vicinity of stationary rotation of the satellite around the normal to the orbital plane
(cylindrical precession). We study the cases where in the limiting case of a circular orbit the
values of the problem parameters (inertial parameter, dimensionless angular velocity, and orbital
eccentricity of the center of mass) belong to small neighborhoods of multiple resonance points
in the parameter space, for which one of frequencies of small linear oscillations of the perturbed
system is zero, and the other is an integer or half-integer number. We solve the problem of the
existence, number, and stability of resonant periodic motions of the satellite, analytic in integer
or fractional powers of a small parameter (orbital eccentricity of the center of mass). The study
is based on previously obtained general theoretical results in the problem of nonlinear oscillations
of a nearly autonomous, time-periodic Hamiltonian system with two degrees of freedom in the
cases of multiple parametric resonances under consideration. Compared to the general theory,
the problem of the stability of periodic satellite motions is studied more fully. For cases where
the nonzero frequency is half-integer, a rigorous nonlinear stability analysis is performed. For
cases where the nonzero frequency is an integer, a complete linear stability analysis is carried
out, and the corresponding stability diagrams are obtained.
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