Your search keyword '"34C07"' showing total 63 results

1. Bifurcation of limit cycles in piecewise quadratic differential systems with an invariant straight line

Author

da Cruz, Leonardo P. C. and Torregrosa, Joan

Subjects

Mathematics - Dynamical Systems, 34C07

Abstract

We solve the center-focus problem in a class of piecewise quadratic polynomial differential systems with an invariant straight line. The separation curve is also a straight line which is not invariant. We provide families having at the origin a weak-foci of maximal order. In the continuous class, the cyclicity problem is also solved, being $3$ such maximal number. Moreover, for the discontinuous class but without sliding segment, we prove the existence of $7$ limit cycles of small amplitude.

Published

2022

2. Limit Cycles from Planar Piecewise Linear Hamiltonian differential Systems with Two or Three Zones

Author

Pessoa, C. and Ribeiro, R.

Subjects

Mathematics - Dynamical Systems, 34C07

Abstract

In this paper, we study the existence of limit cycles in continuous and discontinuous planar piecewise linear Hamiltonian differential systems with two or three zones separated by straight lines and such that the linear systems that define the piecewise one have isolated singular points, i.e. centers or saddles. In this case, we show that if the planar piecewise linear Hamiltonian differential system is either continuous or discontinuous with two zones, then it has no limit cycles. Now, if the planar piecewise linear Hamiltonian differential system is discontinuous with three zones, then it has at most one limit cycle, and there are examples with one limit cycle. More precisely, without taking into account the position of the singular points in the zones, we present examples with the unique limit cycle for all possible combinations of saddles and centers., Comment: 22 pages, 6 figures

Published

2021

3. Non-bifurcation of critical periods from semi-hyperbolic polycycles of quadratic centers

Author

Marín, David, Saavedra, Mariana, and Villadelprat, Jordi

Subjects

Mathematics - Dynamical Systems, 34C07

Abstract

In this paper we consider the unfolding of saddle-node \[ X= \frac{1}{xU_a(x,y)}\Big(x(x^\mu-\varepsilon)\partial_x-V_a(x)y\partial_y\Big), \] parametrized by $(\varepsilon,a)$ with $\varepsilon\approx 0$ and $a$ in an open subset $A$ of $\mathbb R^{\alpha},$ and we study the Dulac time $\mathcal T(s;\varepsilon,a)$ of one of its hyperbolic sectors. We prove (Theorem A) that the derivative $\partial_s\mathcal T(s;\varepsilon,a)$ tends to $-\infty$ as $(s,\varepsilon)\to (0^+,0)$ uniformly on compact subsets of $A.$ This result is addressed to study the bifurcation of critical periods in the Loud's family of quadratic centers. In this regard we show (Theorem B) that no bifurcation occurs from certain semi-hyperbolic polycycles.

Published

2021

4. Limit cycles appearing from perturbations of cubic piecewise smooth center with double invariant real straight lines

Author

Yang, Jihua and Zhao, Liqin

Subjects

Mathematics - Dynamical Systems, 34C07

Abstract

This paper investigates the exact number of limit cycles given by the averaging theory of first order for the piecewise smooth integrable non-Hamiltonian system \begin{eqnarray*} (\dot{x},\ \dot{y})=\begin{cases} (-y(x+a)^2+\varepsilon f^+(x,y),\ x(x+a)^2+\varepsilon g^+(x,y)),\ \ x\geq0,\\ (-y(x+b)^2+\varepsilon f^-(x,y),\ x(x+b)^2+\varepsilon g^-(x,y)),\ ~ \, x<0,\\ \end{cases}\end{eqnarray*} where $ab\neq 0$, $0<|\varepsilon|\ll 1$, and $f^\pm(x,y)$ and $g^\pm(x,y)$ are polynomials of degree $n$. It is proved that the exact number of limit cycles emerging from the period annulus surrounding the origin is linear depending on $n$ and it is at least twice the associated estimation of smooth systems., Comment: 22papges

Published

2018

5. Bifurcation of limit cycles by perturbing piecewise smooth integrable differential systems with four zones

Author

Yang, Jihua and Zhao, Liqin

Subjects

Mathematics - Classical Analysis and ODEs, Mathematics - Dynamical Systems, 34C07

Abstract

This paper deals with the problem of limit cycle bifurcations for piecewise smooth integrable differential systems with four zones. When the unperturbed system has a family of periodic orbits, the first order Melnikov function is derived which can be used to study the number of limit cycles bifurcated from the periodic orbits. As an application, using the first order Melnikov function and Picard-Fuchs equation, we obtain an upper bound of the number of bifurcated limit cycles of a concrete piecewise smooth differential system., Comment: I found that theorem 1 in this paper has been proved in other articles, and the paper needs to be revised

Published

2017

6. Irreducibility of the Picard-Fuchs equation related to the Lotka-Volterra polynomial $ x^2 y^2(1-x-y) $

Author

Gavrilov, Lubomir

Subjects

Mathematics - Dynamical Systems, 34C07

Abstract

We prove that the Zarisky closure of the monodromy group of the polynomial $ x^2 y^2(1-x-y) $ is the symplectic group $Sp(4,\mathbb C)$. This shows that some previous results about this monodromy representation are wrong., Comment: A few typos were corrected

Published

2016

7. Limit cycles for a class of $\mathbb{Z}_{2n}-$equivariant systems without infinite equilibria

Author

Labouriau, Isabel S. and Murza, Adrian C.

Subjects

Mathematics - Dynamical Systems, 34C07

Abstract

We analyze the dynamics of a class of $\mathbb{Z}_{2n}$-equivariant differential equations on the plane, depending on 4 real parameters. This study is the generalisation to $\mathbb{Z}_{2n}$ of previous works with $\mathbb{Z}_4$ and $\mathbb{Z}_6$ symmetry. We reduce the problem of finding limit cycles to an Abel equation, and provide criteria for proving in some cases uniqueness and hyperbolicity of the limit cycle that surrounds either 1, $2n+1$ or $4n+1$ equilibria, the origin being always one of these points.

Published

2015

8. Unfoldings of saddle-nodes and their Dulac time

Author

Mardesić, Pavao, Marín, David, Saavedra, Mariana, and Villadelprat, Jordi

Subjects

Mathematics - Dynamical Systems, 34C07

Abstract

In this paper we study unfoldings of saddle-nodes and their Dulac time. By unfolding a saddle-node, saddles and nodes appear. In the first result (Theorem A) we prove uniform regularity by which orbits and their derivatives arrive at a node. Uniformity is with respect to all parameters including the unfolding parameter bringing the node to a saddle-node and a parameter belonging to a space of functions. In the second part, we apply this first result for proving a regularity result (Theorem B) on the Dulac time (time of Dulac map) of an unfolding of a saddle-node. This result is a building block in the study of bifurcations of critical periods in a neighbourhood of a polycycle. Finally, we apply Theorems A and B to the study of critical periods of the Loud family of quadratic centers and we prove that no bifurcation occurs for certain values of the parameters (Theorem C).

Published

2015

9. An inverse approach to the center-foci problem

Author

Ramírez, Rafael and Ramírez, Valentín

Subjects

Mathematics - Dynamical Systems, 34C07

Abstract

The classical Center-Focus Problem posed by H. Poincar\'e in 1880's is concerned on the characterization of planar polynomial vector fields $X=(-y+P(x,y))\dfrac{\partial}{\partial x}+(x+Q(x,y))\dfrac{\partial}{\partial y},$ with $P(0,0)=Q(0,0)=0,$ such that all their integral trajectories are closed curves whose interiors contain a fixed point called center or such that all their integral trajectories are spirals called foci. In this paper we state and study the inverse problem to the Center-Foci Problem i.e., we require to determine the analytic planar vector fields $X$ in such a way that for a given Liapunov function \[V=V(x,y)=\dfrac{\lambda}{2}(x^2+y^2)+\displaystyle\sum_{j=3}^{\infty} H_j(x,y),\] where $H_j=H_j(x,y)$ are homogenous polynomial of degree $j,$ the following equation holds \[X(V)=\displaystyle\sum_{j=3}^{\infty}V_j(x^2+y^2)^{j+1}, \] where $V_j$ for $j\in\mathbb{N}$ are the Liapunov constants. In particular we study the case when the origin is a center and the vector field is polynomial.

Published

2014

10. Cubic perturbations of elliptic Hamiltonian vector fields of degree three

Author

Gavrilov, Lubomir and Iliev, Iliya D.

Subjects

Mathematics - Dynamical Systems, 34C07

Abstract

The purpose of the present paper is to study the limit cycles of one-parameter perturbed plane Hamiltonian vector field $X_\varepsilon$ $$ X_\varepsilon : \left\{ \begin{array}{llr} \dot{x}=\;\; H_y+\varepsilon f(x,y)\\ \dot{y}=-H_x+\varepsilon g(x,y), \end{array} \;\;\;\;\; H~=\frac{1}{2} y^2~+U(x) \right. $$ which bifurcate from the period annuli of $X_0$ for sufficiently small $\varepsilon$. Here $U$ is a univariate polynomial of degree four without symmetry, and $f, g$ are arbitrary cubic polynomials in two variables. We take a period annulus and parameterize the related displacement map $d(h,\varepsilon)$ by the Hamiltonian value $h$ and by the small parameter $\varepsilon$. Let $M_k(h)$ be the $k$-th coefficient in its expansion with respect to $\varepsilon$. We establish the general form of $M_k$ and study its zeroes. We deduce that the period annuli of $X_0$ can produce for sufficiently small $\varepsilon$, at most 5, 7 or 8 zeroes in the interior eight-loop case, the saddle-loop case, and the exterior eight-loop case respectively. In the interior eight-loop case the bound is exact, while in the saddle-loop case we provide examples of Hamiltonian fields which produce 6 small-amplitude limit cycles. Polynomial perturbations of $X_0$ of higher degrees are also studied.

Published

2014

11. Perturbations of symmetric elliptic Hamiltonians of degree four in a complex domain

Author

Hamed, Bassem Ben, Gargouri, Ameni, and Gavrilov, Lubomir

Subjects

Mathematics - Dynamical Systems, 34C07

Abstract

The cyclicity of the exterior period annulus of the asymmetrically perturbed Duffing oscillator is a well known problem extensively studied in the literature. In the present paper we provide a complete bifurcation diagram for the number of the zeros of the associated Melnikov function in a suitable complex domain., Comment: 11 pages, 5 figures

Published

2014

12. Perturbations of quadratic Hamiltonian two-saddle cycles

Author

Gavrilov, Lubomir and Iliev, Iliya D.

Subjects

Mathematics - Dynamical Systems, 34C07

Abstract

We prove that the number of limit cycles, which bifurcate from a two-saddle loop of a planar quadratic Hamiltonian system, under an arbitrary quadratic deformation, is less than or equal to three.

Published

2013

13. Four limit cycles from perturbing quadratic integrable systems by quadratic polynomials

Author

Yu, Pei and Han, Maoan

Subjects

Mathematics - Dynamical Systems, 34C07, 34C23

Abstract

In this paper, we give a positive answer to the open question: Can there exist 4 limit cycles in quadratic near-integrable polynomial systems? It is shown that when a quadratic integrable system has two centers and is perturbed by quadratic polynomials, it can generate at least 4 limit cycles with (3,1) distribution. The method of Melnikov function is used., Comment: 42 pages, 10 figures

Published

2010

14. Extension aux cycles singuliers du theoreme de Khovanski-Varchenko

Author

Mourtada, Abderaouf

Subjects

Mathematics - Dynamical Systems, 34C07

Abstract

Let dH be a Hamiltonian one form on the real plane, of degre d. We show that, if H is a Morse function, generic at infinity, then there exists a number N(d) depending only on d, such that every small perturbation of dH has at most N(d) limit cycles on the hole real plane, assuming that it's of degre at most d, and that it has a non vanishing Abelian integral along real cycles of dH., Comment: 19 pages

Published

2009

15. Polynomial Differential Equations with Small coefficients

Author

Alwash, M. A. M.

Subjects

Mathematics - Classical Analysis and ODEs, Mathematics - Dynamical Systems, 34C25, 34C07, 34C05

Abstract

Classes of polynomial differential equations of degree n are considered. An explicit upper bound on the size of the coefficients are given which implies that each equation in the class has exactly n complex periodic solutions. In most of the classes the upper bound can be improved when we consider real periodic solutions. We present a proof to a recent conjecture on the number of periodic solutions. The results are used to give upper bounds for the number of limit cycles of polynomial two-dimensional systems., Comment: 15 pages

Published

2009

16. A survey on the inverse integrating factor

Author

García, Isaac A. and Grau, Maite

Subjects

Mathematics - Dynamical Systems, 34C07, 37G15

Abstract

The relation between limit cycles of planar differential systems and the inverse integrating factor was first shown in an article of Giacomini, Llibre and Viano appeared in 1996. From that moment on, many research articles are devoted to the study of the properties of the inverse integrating factor and its relation with limit cycles and their bifurcations. This paper is a summary of all the results about this topic. We include a list of references together with the corresponding related results aiming at being as much exhaustive as possible. The paper is, nonetheless, self-contained in such a way that all the main results on the inverse integrating factor are stated and a complete overview of the subject is given. Each section contains a different issue to which the inverse integrating factor plays a role: the integrability problem, relation with Lie symmetries, the center problem, vanishing set of an inverse integrating factor, bifurcation of limit cycles from either a period annulus or from a monodromic $\omega$-limit set and some generalizations.

Published

2009

17. Limit Cycle Bifurcations in a Quartic Ecological Model

Author

Broer, Henk W. and Gaiko, Valery A.

Subjects

Mathematics - Dynamical Systems, Mathematics - Classical Analysis and ODEs, 34C05, 34C07, 34C23, 37G05, 37G10, 37G15

Abstract

In this paper we complete the global qualitative analysis of a quartic ecological model. In particular, studying global bifurcations of singular points and limit cycles, we prove that the corresponding dynamical system has at most two limit cycles., Comment: 13 pages

Published

2009

18. Generalized Hopf Bifurcation for planar vector fields via the inverse integrating factor

Author

Garcia, Isaac A., Giacomini, Hector, and Grau, Maite

Subjects

Mathematics - Dynamical Systems, Mathematics - Classical Analysis and ODEs, 37G15, 37G10, 34C07

Abstract

In this paper we study the maximum number of limit cycles that can bifurcate from a focus singular point $p_0$ of an analytic, autonomous differential system in the real plane under an analytic perturbation. We consider $p_0$ being a focus singular point of the following three types: non-degenerate, degenerate without characteristic directions and nilpotent. In a neighborhood of $p_0$ the differential system can always be brought, by means of a change to (generalized) polar coordinates $(r, \theta)$, to an equation over a cylinder in which the singular point $p_0$ corresponds to a limit cycle $\gamma_0$. This equation over the cylinder always has an inverse integrating factor which is smooth and non--flat in $r$ in a neighborhood of $\gamma_0$. We define the notion of vanishing multiplicity of the inverse integrating factor over $\gamma_0$. This vanishing multiplicity determines the maximum number of limit cycles that bifurcate from the singular point $p_0$ in the non-degenerate case and a lower bound for the cyclicity otherwise. Moreover, we prove the existence of an inverse integrating factor in a neighborhood of many types of singular points, namely for the three types of focus considered in the previous paragraph and for any isolated singular point with at least one non-zero eigenvalue., Comment: 41 pages, no figures

Published

2009

19. Upper bounds for the number of limit cycles of some planar polynomial differential systems

Author

Gasull, Armengol and Giacomini, Hector

Subjects

Mathematics - Dynamical Systems, Mathematics - Classical Analysis and ODEs, 34C05, 34C07

Abstract

We give an effective method for controlling the maximum number of limit cycles of some planar polynomial systems. It is based on a suitable choice of a Dulac function and the application of the well-known Bendixson-Dulac Criterion for multiple connected regions. The key point is a new approach to control the sign of the functions involved in the criterion. The method is applied to several examples., Comment: 14 pages, O figures

Published

2008

20. On the motion under focal attraction in a rotating medium

Author

Sotomayor, Jorge

Subjects

Mathematics - Dynamical Systems, Mathematics - Classical Analysis and ODEs, 34C07, 34C99

Abstract

New results are established here on the phase portraits and bifurcations of the kinematic model in a system of ODE's, first presented by H.K. Wilson in his 1971 book, and by him attributed to L. Markus (unpublished). A new, self-sufficient, study which extends Wilson's result and allows an essential conclusion for the applicability of the model is reported here.

Published

2008

21. On limit cycles appearing by polynomial perturbation of Darbouxian integrable systems

Author

Novikov, Dmitry

Subjects

Mathematics - Classical Analysis and ODEs, Mathematics - Dynamical Systems, 34C07, 44A10

Abstract

We prove an existential finiteness Varchenko-Khovanskii type result for integrals of rational 1-forms over the level curves of Darbouxian integrals., Comment: 21 pages, 2 figures, LaTeX

Published

2007

22. Quadratic centers defining elliptic surfaces

Author

Gautier, Sebastien

Subjects

Mathematics - Dynamical Systems, 34C07

Abstract

Let $X$ be a quadratic vector field with a center whose generic orbits are algebraic curves of genus one. To each $X$ we associate an elliptic surface (a smooth complex compact surface which is a genus one fibration). We give the list of all such vector fields and determine the corresponding elliptic surfaces., Comment: 24 pages, 16 Figures, 8 Tables

Published

2007

23. On Center Sets of ODEs Determined by Moments of their Coefficients

Author

Brudnyi, Alexander

Subjects

Mathematics - Dynamical Systems, Mathematics - Algebraic Geometry, 34C07

Abstract

The classical H. Poincar\'{e} Center-Focus problem asks about the characterization of planar polynomial vector fields such that all their integral trajectories are closed curves whose interiors contain a fixed point, a {\em center}. This problem can be reduced to a center problem for some ordinary differential equation whose coefficients are trigonometric polynomials depending polynomially on the coefficients of the field. In this paper we show that the set of centers in the Center-Focus problem can be determined as the set of zeros of some continuous functions from the moments of coefficients of this equation., Comment: 16 pages

Published

2007

24. Formal Paths, Iterated Integrals and the Center Problem for Ordinary Differential Equations

Author

Brudnyi, Alexander

Subjects

Mathematics - Dynamical Systems, Mathematics - Classical Analysis and ODEs, 32E20, 34C07

Abstract

We continue the study of the center problem for the ordinary differential equation $v'=\sum_{i=1}^{\infty}a_{i}(x)v^{i+1}$ started in our earlier papers. In this paper we present the highlights of the algebraic theory of centers., Comment: 35 pages

Published

2007

25. A new uniqueness criterion for the number of periodic orbits of Abel equations

Author

Alvarez, M. J., Gasull, A., and Giacomini, H.

Subjects

Mathematics - Dynamical Systems, 34C05, 34C07

Abstract

A solution of the Abel equation $\dot{x}=A(t)x^3+B(t)x^2$ such that $x(0)=x(1)$ is called a periodic orbit of the equation. Our main result proves that if there exist two real numbers $a$ and $b$ such that the function $aA(t)+bB(t)$ is not identically zero, and does not change sign in $[0,1]$ then the Abel differential equation has at most one non-zero periodic orbit. Furthermore, when this periodic orbit exists, it is hyperbolic. This result extends the known criteria about the Abel equation that only refer to the cases where either $A(t)\not\equiv0$ or $B(t)\not\equiv0$ does not change sign. We apply this new criterion to study the number of periodic solutions of two simple cases of Abel equations: the one where the functions $A(t)$ and $B(t)$ are 1-periodic trigonometric polynomials of degree one and the case where these two functions are polynomials with three monomials. Finally, we give an upper bound for the number of isolated periodic orbits of the general Abel equation $\dot{x}=A(t)x^3+B(t)x^2+C(t)x,$ when $A(t), B(t)$ and $C(t)$ satisfy adequate conditions., Comment: 17 pages; no figures

Published

2006

26. On Poincar\'e's Fourth and Fifth Examples of Limit Cycles at Infinity

Author

Roeder, Roland K. W.

Subjects

Mathematics - Dynamical Systems, Mathematics - History and Overview, 37C10, 34C04, 34C07

Abstract

Errors are found in example problems from Henri Poincar\'e's paper ``M\'emoire sur les courbes d\'efinies par une \'equation diff\'erentielle.'' Examples four and five from chapter seven and examples one, two, and three from chapter nine do not have the limit cycles at infinity predicted by Poincar\'e. Instead they have fixed points at every point at infinity. In order to understand the errors made by Poincar\'e, examples four and five are studied at length. Replacement equations for the fourth and fifth examples are suggested based on the supposition that terms were omitted from Poincar\'e's equations., Comment: 22 pages

Published

2006

27. On the stability of limit cycles for planar differential systems

Author

Giacomini, Hector and Grau, Maite

Subjects

Mathematics - Dynamical Systems, 34C05, 34C07, 34D20

Abstract

We consider a planar differential system $\dot{x}= P(x,y)$, $\dot{y} = Q(x,y)$, where $P$ and $Q$ are $\mathcal{C}^1$ functions in some open set $\mathcal{U} \subseteq \mathbb{R}^2$, and $\dot{}=\frac{d}{dt}$. Let $\gamma$ be a periodic orbit of the system in $\mathcal{U}$. Let $f(x,y): \mathcal{U} \subseteq \mathbb{R}^2 \to \mathbb{R}$ be a $\mathcal{C}^1$ function such that \[ P(x,y) \frac{\partial f}{\partial x}(x,y) + Q(x,y) \frac{\partial f}{\partial y} (x,y) = k(x,y) f(x,y), \] where $k(x,y)$ is a $\mathcal{C}^1$ function in $\mathcal{U}$ and $\gamma \subseteq \{(x,y) | f(x,y) = 0\}$. We assume that if $p \in \mathcal{U}$ is such that $f(p)=0$ and $\nabla f(p)=0$, then $p$ is a singular point. We prove that $\int_{0}^{T} (\frac{\partial P}{\partial x} + \frac{\partial Q}{\partial y})(\gamma(t)) dt= \int_0^{T} k(\gamma(t)) dt$, where $T>0$ is the period of $\gamma$. As an application, we take profit from this equality to show the hyperbolicity of the known algebraic limit cycles of quadratic systems., Comment: 22 pages, no figures

Published

2005

28. Uniqueness of limit cycles for a class of planar vector fields

Author

Carletti, Timoteo

Subjects

Mathematics - Classical Analysis and ODEs, Mathematics - Dynamical Systems, 34C07

Abstract

In this paper we give sufficient conditions to ensure uniqueness of limit cycles for a class of planar vector fields. We also exhibit a class of examples with exactly one limit cycle., Comment: 8 pages, 2 figures

Published

2004

29. Complete hyperelliptic integrals of the first kind and their non-oscillation

Author

Gavrilov, Lubomir and Iliev, Iliya D.

Subjects

Mathematics - Dynamical Systems, 34C07, 3408, 70K05

Abstract

Let $P(x)$ be a real polynomial of degree $2g+1$, $H=y^2+P(x)$ and $\delta(h)$ be an oval contained in the level set $\{H=h\}$. We study complete Abelian integrals of the form $$I(h)=\int_{\delta(h)} \frac{(\alpha_0+\alpha_1 x+... + \alpha_{g-1}x^{g-1})dx}{y}, h\in \Sigma,$$ where $\alpha_i$ are real and $\Sigma\subset \R$ is a maximal open interval on which a continuous family of ovals $\{\delta(h)\}$ exists. We show that the $g$-dimensional real vector space of these integrals is not Chebyshev in general: for any $g>1$, there are hyperelliptic Hamiltonians $H$ and continuous families of ovals $\delta(h)\subset\{H=h\}$, $h\in\Sigma$, such that the Abelian integral $I(h)$ can have at least $[\frac32g]-1$ zeros in $\Sigma$. Our main result is Theorem \ref{main} in which we show that when $g=2$, exceptional families of ovals $\{\delta(h)\}$ exist, such that the corresponding vector space is still Chebyshev.

Published

2002

30. A Jensen Inequality for a Family of Analytic Functions

Author

Brudnyi, Alex

Subjects

Mathematics - Complex Variables, Mathematics - Dynamical Systems, 34C07, 46E15

Abstract

We improve an estimate (obtained in "A.Brudnyi, Small amplitude limit cycles and the distribution of zeros of families of analytic functions, Ann. of Math. 154 (2) (2001), 227-243") for the average number of limit cycles of a planar polynomial vector field situated in a neighbourhood of the origin provided that the field in a larger neighbourhood is close enough to a linear center. The result follows from a new distributional inequality for the number of zeros of a family of univariate holomorphic functions depending holomorphically on a parameter.

Published

2001

31. Redundant Picard-Fuchs system for Abelian integrals

Author

Novikov, D. and Yakovenko, S.

Subjects

Mathematics - Dynamical Systems, Mathematics - Complex Variables, 34C07, 34C08, 32S40, 14D05, 14K20, 32S20

Abstract

We derive an explicit system of Picard-Fuchs differential equations satisfied by Abelian integrals of monomial forms and majorize its coefficients. A peculiar feature of this construction is that the system admitting such explicit majorants, appears only in dimension approximately two times greater than the standard Picard-Fuchs system. The result is used to obtain a partial solution to the tangential Hilbert 16th problem. We establish upper bounds for the number of zeros of arbitrary Abelian integrals on a positive distance from the critical locus. Under the additional assumption that the critical values of the Hamiltonian are distant from each other (after a proper normalization), we were able to majorize the number of all (real and complex) zeros. In the second part of the paper an equivariant formulation of the above problem is discussed and relationships between spread of critical values and non-homogeneity of uni- and bivariate complex polynomials are studied., Comment: 31 page, LaTeX2e (amsart)

Published

2000

32. Bifurcation of limit cycles in piecewise quadratic differential systems with an invariant straight line

Author

Leonardo P.C. da Cruz and Joan Torregrosa

Subjects

Lyapunov quantities, Limit cycles, Applied Mathematics, 34C07, FOS: Mathematics, Cyclicity, Dynamical Systems (math.DS), Mathematics - Dynamical Systems, Weak-focus order, Center-focus, Analysis

Abstract

Altres ajuts: acords transformatius de la UAB We solve the center-focus problem in a class of piecewise quadratic polynomial differential systems with an invariant straight line. The separation curve is also a straight line which is not invariant. We provide families having at the origin a weak-foci of maximal order. In the continuous class, the cyclicity problem is also solved, being 3 such maximal number. Moreover, for the discontinuous class but without sliding segment, we prove the existence of 7 limit cycles of small amplitude.

Published

2022

33. The Center Problem for the Lotka Reactions with Generalized Mass-Action Kinetics

Author

Georg Regensburger, Josef Hofbauer, Stefan Müller, and Balázs Boros

Subjects

Mass action kinetics, Mathematical optimization, Dynamical systems theory, Reversible system, Molecular Networks (q-bio.MN), Kinetics, 92E20, 34C25, 02 engineering and technology, Center (group theory), Dynamical Systems (math.DS), Center-focus problem, 01 natural sciences, Chemical reaction, Article, Simple (abstract algebra), 0202 electrical engineering, electronic engineering, information engineering, FOS: Mathematics, Discrete Mathematics and Combinatorics, Quantitative Biology - Molecular Networks, First integral, Statistical physics, 0101 mathematics, Positive equilibrium, Mathematics - Dynamical Systems, Power-law kinetics, Mathematics, Applied Mathematics, Focal value, Ode, 010101 applied mathematics, FOS: Biological sciences, 34C07, 020201 artificial intelligence & image processing, Chemical reaction network

Abstract

Chemical reaction networks with generalized mass-action kinetics lead to power-law dynamical systems. As a simple example, we consider the Lotka reactions and the resulting planar ODE. We characterize the parameters (positive coefficients and real exponents) for which the unique positive equilibrium is a center.

Published

2017

34. Unfolding of saddle-nodes and their Dulac time

Author

Mariana Saavedra, Pavao Mardešić, Jordi Villadelprat, David Marín, Institut de Mathématiques de Bourgogne [Dijon] (IMB), Centre National de la Recherche Scientifique (CNRS)-Université de Franche-Comté (UFC), Université Bourgogne Franche-Comté [COMUE] (UBFC)-Université Bourgogne Franche-Comté [COMUE] (UBFC)-Université de Bourgogne (UB), Departament de Matemàtiques [Barcelona] (UAB), Universitat Autònoma de Barcelona (UAB), Departamento de Matematicas, Universidad de Concepcion, Universidad de Concepción [Chile], Departament d'Enginyeria Informàtica i Matemàtiques, Universitat Rovira i Virgili, FONDECYT. Grant number : 1120333, MINECO/FEDER. Grant number : MTM2011-26674-C02-01, MTM-2008-03437, ERDF 'A way to build Europe'. Grant number : UNAB10-4E-378, ANR-11-BS01-0009,STAAVF,Singularités de Trajectoires de Champs de Vecteurs Analytiques et Algébriques(2011), Institut de Mathématiques de Bourgogne [Dijon] ( IMB ), Université de Bourgogne ( UB ) -Centre National de la Recherche Scientifique ( CNRS ), Departament de Matemàtiques [Barcelona], Universitat Autònoma de Barcelona [Barcelona] ( UAB ), Departamento de Matematicas (Universidad de Concepcion, Chile), Universidad de Concepcion, and ANR-11-BS01-0009,STAAVF,Singularités de Trajectoires de Champs de Vecteurs Analytiques et Algébriques ( 2011 )

Subjects

[ MATH.MATH-DS ] Mathematics [math]/Dynamical Systems [math.DS], [MATH.MATH-DS]Mathematics [math]/Dynamical Systems [math.DS], Block (permutation group theory), Dynamical Systems (math.DS), Space (mathematics), 01 natural sciences, Combinatorics, Quadratic equation, FOS: Mathematics, Mathematics - Dynamical Systems, 0101 mathematics, Bifurcation, Saddle, Mathematics, Period function, Applied Mathematics, Unfolding of a saddle-node, 010102 general mathematics, 16. Peace & justice, 010101 applied mathematics, MSC: 34C07, Asymptotic expansions, 34C07, Node (circuits), Asymptotic expansion, Analysis

Abstract

Altres ajuts: UNAB10-4E-378, co-funded by ERDF "A way to build Europe" and by the French ANR-11-BS01-0009 STAAVF. In this paper we study unfoldings of saddle-nodes and their Dulac time. By unfolding a saddle-node, saddles and nodes appear. In the first result (Theorem A) we give a uniform asymptotic expansion of the trajectories arriving at the node. Uniformity is with respect to all parameters including the unfolding parameter bringing the node to a saddle-node and a parameter belonging to a space of functions. In the second part, we apply this first result for proving a regularity result (Theorem B) on the Dulac time (time of Dulac map) of an unfolding of a saddle-node. This result is a building block in the study of bifurcations of critical periods in a neighborhood of a polycycle. Finally, we apply Theorem A and Theorem B to the study of critical periods of the Loud family of quadratic centers and we prove that no bifurcation occurs for certain values of the parameters (Theorem C).

Published

2016

35. A Survey on the Inverse Integrating Factor

Author

Isaac A. García and Maite Grau

Subjects

37G15, Inverse, Dynamical Systems (math.DS), Integrability, Integrating factor, 34-02, 34C07, Limit cycle, FOS: Mathematics, Discrete Mathematics and Combinatorics, Limit (mathematics), Mathematics - Dynamical Systems, Poincaré map, Mathematics, Applied Mathematics, Annulus (mathematics), Lie symmetry, Algebra, Moment (mathematics), Homogeneous space, Inverse integrating factor, Bifurcation, Monodromic graphic

Abstract

El pdf de l'article és la versió preprint: arXiv:0903.0941 The relation between limit cycles of planar differential systems and the inverse integrating factor was first shown in an article of Giacomini, Llibre and Viano appeared in 1996. From that moment on, many research articles are devoted to the study of the properties of the inverse integrating factor and its relationwith limit cycles and their bifurcations. This paper is a summary of all the results about this topic. We include a list of references together with the corresponding related results aiming at being as much exhaustive as possible. The paper is, nonetheless, self-contained in such a way that all the main results on the inverse integrating factor are stated and a complete overview of the subject is given. Each section contains a different issue to which the inverse integrating factor plays a role: the integrability problem, relation with Lie symmetries, the center problem, vanishing set of an inverse integrating factor, bifurcation of limit cycles from either a period annulus or from a monodromic ω-limit set and some generalizations.

Published

2010

36. Quadratic centers defining elliptic surfaces

Author

Sebastien Gautier

Subjects

Applied Mathematics, Mathematical analysis, Dynamical Systems (math.DS), Twists of curves, Supersingular elliptic curve, Jacobi elliptic functions, Elliptic curve, Mathematics::Algebraic Geometry, 34C07, Genus (mathematics), Algebraic surface, FOS: Mathematics, Elliptic surface, Mathematics - Dynamical Systems, Schoof's algorithm, Analysis, Mathematics

Abstract

Let $X$ be a quadratic vector field with a center whose generic orbits are algebraic curves of genus one. To each $X$ we associate an elliptic surface (a smooth complex compact surface which is a genus one fibration). We give the list of all such vector fields and determine the corresponding elliptic surfaces., 24 pages, 16 Figures, 8 Tables

Published

2008

37. A new uniqueness criterion for the number of periodic orbits of Abel equations

Author

Armengol Gasull, Hector Giacomini, M.J. Álvarez, Laboratoire de Mathématiques et Physique Théorique (LMPT), Université de Tours-Centre National de la Recherche Scientifique (CNRS), and Université de Tours (UT)-Centre National de la Recherche Scientifique (CNRS)

Subjects

Pure mathematics, Differential equation, [MATH.MATH-DS]Mathematics [math]/Dynamical Systems [math.DS], Dynamical Systems (math.DS), 34C05, 01 natural sciences, FOS: Mathematics, Uniqueness, 0101 mathematics, Mathematics - Dynamical Systems, Real number, Mathematics, Discrete mathematics, Applied Mathematics, 010102 general mathematics, Zero (complex analysis), Abel equation, Function (mathematics), 34C07, 010101 applied mathematics, Periodic orbit, Abel's identity, Analysis, Sign (mathematics)

Abstract

A solution of the Abel equation $\dot{x}=A(t)x^3+B(t)x^2$ such that $x(0)=x(1)$ is called a periodic orbit of the equation. Our main result proves that if there exist two real numbers $a$ and $b$ such that the function $aA(t)+bB(t)$ is not identically zero, and does not change sign in $[0,1]$ then the Abel differential equation has at most one non-zero periodic orbit. Furthermore, when this periodic orbit exists, it is hyperbolic. This result extends the known criteria about the Abel equation that only refer to the cases where either $A(t)\not\equiv0$ or $B(t)\not\equiv0$ does not change sign. We apply this new criterion to study the number of periodic solutions of two simple cases of Abel equations: the one where the functions $A(t)$ and $B(t)$ are 1-periodic trigonometric polynomials of degree one and the case where these two functions are polynomials with three monomials. Finally, we give an upper bound for the number of isolated periodic orbits of the general Abel equation $\dot{x}=A(t)x^3+B(t)x^2+C(t)x,$ when $A(t), B(t)$ and $C(t)$ satisfy adequate conditions., 17 pages; no figures

Published

2007

38. Bifurcation values for a family of planar vector fields of degree five

Author

Hector Giacomini, Johanna D. García-Saldaña, Armengol Gasull, Laboratoire de Mathématiques et Physique Théorique (LMPT), Université de Tours-Centre National de la Recherche Scientifique (CNRS), Université de Tours (UT)-Centre National de la Recherche Scientifique (CNRS), and Giacomini, Hector

Subjects

34C07, 34C23, 34C25, 37C27, 13P15, Differential equation, [MATH.MATH-DS]Mathematics [math]/Dynamical Systems [math.DS], [MATH.MATH-DS] Mathematics [math]/Dynamical Systems [math.DS], Dynamical Systems (math.DS), Bifurcation diagram, planar vector fields, FOS: Mathematics, Discrete Mathematics and Combinatorics, Limit (mathematics), Mathematics - Dynamical Systems, Polynomial planar system, Mathematics, Dulac function, Degree (graph theory), Primary: 34C07, Secondary: 34C23, 34C25, 37C27, 13P15, Double discriminant, Applied Mathematics, Mathematical analysis, Phase portrait on the Poincaré sphere, polynomial planar system, Discriminant, Flow (mathematics), bifurcation, uniqueness of limit cycles, Vector field, Bifurcation, Algebraic curve, Uniqueness of limit cycles, bifurcations, Analysis

Abstract

We study the number of limit cycles and the bifurcation diagram in the Poincar\'{e} sphere of a one-parameter family of planar differential equations of degree five $\dot {\bf x}=X_b({\bf x})$ which has been already considered in previous papers. We prove that there is a value $b^*>0$ such that the limit cycle exists only when $b\in(0,b^*)$ and that it is unique and hyperbolic by using a rational Dulac function. Moreover we provide an interval of length 27/1000 where $b^*$ lies. As far as we know the tools used to determine this interval are new and are based on the construction of algebraic curves without contact for the flow of the differential equation. These curves are obtained using analytic information about the separatrices of the infinite critical points of the vector field. To prove that the Bendixson-Dulac Theorem works we develop a method for studying whether one-parameter families of polynomials in two variables do not vanish based on the computation of the so called double discriminant., Comment: 33 pages, 14 figures

Published

2015

39. Uniqueness of limit cycles for a class of planar vector fields

Author

Timoteo Carletti

Subjects

Class (set theory), Applied Mathematics, Mathematical analysis, Planar vector fields, Dynamical Systems (math.DS), planar vector fields, Mathematics - Classical Analysis and ODEs, 34C07, Limit cycle, Classical Analysis and ODEs (math.CA), FOS: Mathematics, uniqueness of limit cycles, Discrete Mathematics and Combinatorics, Limit (mathematics), Uniqueness, Mathematics - Dynamical Systems, Liénard-like systems, Mathematics

Abstract

In this paper we give sufficient conditions to ensure uniqueness of limit cycles for a class of planar vector fields. We also exhibit a class of examples with exactly one limit cycle., 8 pages, 2 figures

Published

2005

40. Cubic perturbations of elliptic Hamiltonian vector fields of degree three

Author

Lubomir Gavrilov and Iliya D. Iliev

Subjects

Hamiltonian vector field, Applied Mathematics, 010102 general mathematics, Dynamical Systems (math.DS), 01 natural sciences, 010101 applied mathematics, symbols.namesake, 34C07, symbols, FOS: Mathematics, Vector field, 0101 mathematics, Mathematics - Dynamical Systems, Hamiltonian (quantum mechanics), Cubic function, Analysis, Mathematics, Mathematical physics

Abstract

The purpose of the present paper is to study the limit cycles of one-parameter perturbed plane Hamiltonian vector field X e X e : { x ˙ = H y + e f ( x , y ) y ˙ = − H x + e g ( x , y ) , H = 1 2 y 2 + U ( x ) which bifurcate from the period annuli of X 0 for sufficiently small e . Here U is a univariate polynomial of degree four without symmetry, and f , g are arbitrary cubic polynomials in two variables. We take a period annulus and parameterize the related displacement map d ( h , e ) by the Hamiltonian value h and by the small parameter e . Let M k ( h ) be the k -th coefficient in its expansion with respect to e . We establish the general form of M k and study its zeroes. We deduce that the period annuli of X 0 can produce for sufficiently small e , at most 5, 7 or 8 zeroes in the interior eight-loop case, the saddle-loop case, and the exterior eight-loop case respectively. In the interior eight-loop case the bound is exact, while in the saddle-loop case we provide examples of Hamiltonian fields which produce 6 small-amplitude limit cycles. Polynomial perturbations of X 0 of higher degrees are also studied.

Published

2014

41. Perturbations of symmetric elliptic Hamiltonians of degree four in a complex domain

Author

Ameni Gargouri, Bassem Ben Hamed, Lubomir Gavrilov, Laboratoire Stabilité et Contrôle des Systèmes (LSCS), Faculté des Sciences de Sfax, Université de Sfax - University of Sfax-Université de Sfax - University of Sfax, Institut de Mathématiques de Toulouse UMR5219 (IMT), Université Toulouse Capitole (UT Capitole), Université de Toulouse (UT)-Université de Toulouse (UT)-Institut National des Sciences Appliquées - Toulouse (INSA Toulouse), Institut National des Sciences Appliquées (INSA)-Université de Toulouse (UT)-Institut National des Sciences Appliquées (INSA)-Université Toulouse - Jean Jaurès (UT2J), Université de Toulouse (UT)-Université Toulouse III - Paul Sabatier (UT3), Université de Toulouse (UT)-Centre National de la Recherche Scientifique (CNRS), Institut National des Sciences Appliquées - Toulouse (INSA Toulouse), Institut National des Sciences Appliquées (INSA)-Institut National des Sciences Appliquées (INSA)-Université Toulouse 1 Capitole (UT1), Université Fédérale Toulouse Midi-Pyrénées-Université Fédérale Toulouse Midi-Pyrénées-Université Toulouse - Jean Jaurès (UT2J)-Université Toulouse III - Paul Sabatier (UT3), and Université Fédérale Toulouse Midi-Pyrénées-Centre National de la Recherche Scientifique (CNRS)

Subjects

Degree (graph theory), Applied Mathematics, 010102 general mathematics, Mathematical analysis, [MATH.MATH-DS]Mathematics [math]/Dynamical Systems [math.DS], Duffing equation, Annulus (mathematics), Dynamical Systems (math.DS), Bifurcation diagram, 01 natural sciences, Domain (mathematical analysis), 010101 applied mathematics, Nonlinear Sciences::Chaotic Dynamics, 34C07, FOS: Mathematics, Mathematics - Dynamical Systems, 0101 mathematics, Nonlinear Sciences::Pattern Formation and Solitons, Analysis, Melnikov method, ComputingMilieux_MISCELLANEOUS, Mathematics

Abstract

The cyclicity of the exterior period annulus of the asymmetrically perturbed Duffing oscillator is a well known problem extensively studied in the literature. In the present paper we provide a complete bifurcation diagram for the number of the zeros of the associated Melnikov function in a suitable complex domain., Comment: 11 pages, 5 figures

Published

2014

42. Generalized Hopf Bifurcation for planar vector fields via the inverse integrating factor

Author

Hector Giacomini, Maite Grau, Isaac A. García, Laboratoire de Mathématiques et Physique Théorique (LMPT), Université de Tours-Centre National de la Recherche Scientifique (CNRS), and Université de Tours (UT)-Centre National de la Recherche Scientifique (CNRS)

Subjects

Regular singular point, [MATH.MATH-DS]Mathematics [math]/Dynamical Systems [math.DS], 37G15, Dynamical Systems (math.DS), [MATH.MATH-CA]Mathematics [math]/Classical Analysis and ODEs [math.CA], Singular point of a curve, 01 natural sciences, 37G10, Integrating factor, symbols.namesake, Singular solution, Limit cycle, Classical Analysis and ODEs (math.CA), FOS: Mathematics, Hopf bifurcation, planar vector field, Mathematics - Dynamical Systems, 0101 mathematics, Eigenvalues and eigenvectors, Mathematics, 34C07, 010102 general mathematics, Mathematical analysis, inverse integrating factor, 010101 applied mathematics, Mathematics - Classical Analysis and ODEs, Ordinary differential equation, symbols, Analysis

Abstract

In this paper we study the maximum number of limit cycles that can bifurcate from a focus singular point $p_0$ of an analytic, autonomous differential system in the real plane under an analytic perturbation. We consider $p_0$ being a focus singular point of the following three types: non-degenerate, degenerate without characteristic directions and nilpotent. In a neighborhood of $p_0$ the differential system can always be brought, by means of a change to (generalized) polar coordinates $(r, \theta)$, to an equation over a cylinder in which the singular point $p_0$ corresponds to a limit cycle $\gamma_0$. This equation over the cylinder always has an inverse integrating factor which is smooth and non--flat in $r$ in a neighborhood of $\gamma_0$. We define the notion of vanishing multiplicity of the inverse integrating factor over $\gamma_0$. This vanishing multiplicity determines the maximum number of limit cycles that bifurcate from the singular point $p_0$ in the non-degenerate case and a lower bound for the cyclicity otherwise. Moreover, we prove the existence of an inverse integrating factor in a neighborhood of many types of singular points, namely for the three types of focus considered in the previous paragraph and for any isolated singular point with at least one non-zero eigenvalue., Comment: 41 pages, no figures

Published

2011

43. Upper bounds for the number of limit cycles of some planar polynomial differential systems

Author

Hector Giacomini, Armengol Gasull, Laboratoire de Mathématiques et Physique Théorique (LMPT), Université de Tours-Centre National de la Recherche Scientifique (CNRS), and Université de Tours (UT)-Centre National de la Recherche Scientifique (CNRS)

Subjects

Polynomial, Mathematics::Dynamical Systems, [MATH.MATH-DS]Mathematics [math]/Dynamical Systems [math.DS], Dynamical Systems (math.DS), [MATH.MATH-CA]Mathematics [math]/Classical Analysis and ODEs [math.CA], 34C05, Differential systems, 01 natural sciences, Planar, Limit cycle, Classical Analysis and ODEs (math.CA), FOS: Mathematics, Discrete Mathematics and Combinatorics, Applied mathematics, Effective method, Limit (mathematics), Mathematics - Dynamical Systems, 0101 mathematics, Mathematics, Applied Mathematics, 010102 general mathematics, Dulac function, 16. Peace & justice, 34C07, 010101 applied mathematics, Mathematics - Classical Analysis and ODEs, Analysis, Sign (mathematics)

Abstract

We give an effective method for controlling the maximum number of limit cycles of some planar polynomial systems. It is based on a suitable choice of a Dulac function and the application of the well-known Bendixson-Dulac Criterion for multiple connected regions. The key point is a new approach to control the sign of the functions involved in the criterion. The method is applied to several examples., Comment: 14 pages, O figures

Published

2010

44. On the finite cyclicity of open period annuli

Author

Dmitry Novikov, Lubomir Gavrilov, Institut de Mathématiques de Toulouse UMR5219 (IMT), Institut National des Sciences Appliquées - Toulouse (INSA Toulouse), Institut National des Sciences Appliquées (INSA)-Institut National des Sciences Appliquées (INSA)-Université Toulouse 1 Capitole (UT1), Université Fédérale Toulouse Midi-Pyrénées-Université Fédérale Toulouse Midi-Pyrénées-Université Toulouse - Jean Jaurès (UT2J)-Université Toulouse III - Paul Sabatier (UT3), Université Fédérale Toulouse Midi-Pyrénées-Centre National de la Recherche Scientifique (CNRS), Université Toulouse Capitole (UT Capitole), Université de Toulouse (UT)-Université de Toulouse (UT)-Institut National des Sciences Appliquées - Toulouse (INSA Toulouse), Institut National des Sciences Appliquées (INSA)-Université de Toulouse (UT)-Institut National des Sciences Appliquées (INSA)-Université Toulouse - Jean Jaurès (UT2J), Université de Toulouse (UT)-Université Toulouse III - Paul Sabatier (UT3), and Université de Toulouse (UT)-Centre National de la Recherche Scientifique (CNRS)

Subjects

34C07, 34C10, General Mathematics, 010102 general mathematics, Mathematical analysis, 34C07 (34C25 37C10 37G15 37J05), Dynamical Systems (math.DS), 34C10, 01 natural sciences, 010101 applied mathematics, symbols.namesake, Relatively compact subspace, 34C07, FOS: Mathematics, symbols, Vector field, Mathematics - Dynamical Systems, 0101 mathematics, Hamiltonian (quantum mechanics), ComputingMilieux_MISCELLANEOUS, Mathematics

Abstract

Let $\Pi$ be an open, relatively compact period annulus of real analytic vector field $X_0$ on an analytic surface. We prove that the maximal number of limit cycles which bifurcate from $\Pi$ under a given multi-parameter analytic deformation $X_\lambda$ of $X_0$ is finite, provided that $X_0$ is either Hamiltonian, or generic Darbouxian vector field., Comment: 22 pages, 1 figure

Published

2010

45. Polynomial Differential Equations with Small coefficients

Author

M. A. M. Alwash

Subjects

Class (set theory), Polynomial, Pure mathematics, Conjecture, Degree (graph theory), Differential equation, Applied Mathematics, 34C25, Dynamical Systems (math.DS), 34C05, Upper and lower bounds, 34C07, Mathematics - Classical Analysis and ODEs, ComputingMethodologies_SYMBOLICANDALGEBRAICMANIPULATION, Classical Analysis and ODEs (math.CA), FOS: Mathematics, Discrete Mathematics and Combinatorics, Limit (mathematics), Mathematics - Dynamical Systems, Hilbert's sixteenth problem, Analysis, Mathematics

Abstract

Classes of polynomial differential equations of degree n are considered. An explicit upper bound on the size of the coefficients are given which implies that each equation in the class has exactly n complex periodic solutions. In most of the classes the upper bound can be improved when we consider real periodic solutions. We present a proof to a recent conjecture on the number of periodic solutions. The results are used to give upper bounds for the number of limit cycles of polynomial two-dimensional systems., Comment: 15 pages

Published

2009

46. On the motion under focal attraction in a rotating medium

Author

Jorge Sotomayor

Subjects

Phase portrait, General Mathematics, High Energy Physics::Lattice, Ode, Motion (geometry), phase portrait, Kinematics, Dynamical Systems (math.DS), stability, 58C23, 34C99, Stability (probability), Attraction, Classical mechanics, Mathematics - Classical Analysis and ODEs, Control theory, 34C07, bifurcation, Classical Analysis and ODEs (math.CA), FOS: Mathematics, Mathematics - Dynamical Systems, Bifurcation, Mathematics

Abstract

New results are established here on the phase portraits and bifurcations of the kinematic model in a system of ODE's, first presented by H.K. Wilson in his 1971 book, and by him attributed to L. Markus (unpublished). A new, self-sufficient, study which extends Wilson's result and allows an essential conclusion for the applicability of the model is reported here.

Published

2008

47. On limit cycles appearing by polynomial perturbation of Darbouxian integrable systems

Author

Dmitry Novikov

Subjects

Pure mathematics, 34C07, 44A10, Integrable system, Mathematical analysis, Perturbation (astronomy), Dynamical Systems (math.DS), Mathematics - Classical Analysis and ODEs, Computer Science::Logic in Computer Science, Classical Analysis and ODEs (math.CA), FOS: Mathematics, Geometry and Topology, Mathematics - Dynamical Systems, Analysis, Mathematics

Abstract

We prove an existential finiteness Varchenko-Khovanskii type result for integrals of rational 1-forms over the level curves of Darbouxian integrals., 21 pages, 2 figures, LaTeX

Published

2007

48. Formal Paths, Iterated Integrals and the Center Problem for Ordinary Differential Equations

Author

Alexander Brudnyi

Subjects

Pure mathematics, Mathematics(all), Differential equation, General Mathematics, Mathematics::General Topology, Dynamical Systems (math.DS), 32E20, Center, Classical Analysis and ODEs (math.CA), FOS: Mathematics, Center (algebra and category theory), Mathematics - Dynamical Systems, Mathematics, Mathematical analysis, Abel equation, Lipschitz continuity, Group of formal paths, Mathematics - Classical Analysis and ODEs, Ordinary differential equation, Algebraic theory, 34C07, Path integral formulation, Iterated integral, Differential algebraic equation

Abstract

We continue the study of the center problem for the ordinary differential equation $v'=\sum_{i=1}^{\infty}a_{i}(x)v^{i+1}$ started in our earlier papers. In this paper we present the highlights of the algebraic theory of centers., 35 pages

Published

2007

49. On the stability of limit cycles for planar differential systems

Author

Hector Giacomini, Maite Grau, Laboratoire de Mathématiques et Physique Théorique (LMPT), Université de Tours (UT)-Centre National de la Recherche Scientifique (CNRS), and Université de Tours-Centre National de la Recherche Scientifique (CNRS)

Subjects

Hyperbolicity, Planar differential system, [MATH.MATH-DS]Mathematics [math]/Dynamical Systems [math.DS], Dynamical Systems (math.DS), Singular point of a curve, 34C05, Differential systems, 01 natural sciences, 34D20, Planar, Polynomial vector field, 34C07, FOS: Mathematics, Limit (mathematics), 0101 mathematics, Mathematics - Dynamical Systems, Mathematics, Discrete mathematics, Applied Mathematics, 010102 general mathematics, Limit cycle, Function (mathematics), 010101 applied mathematics, Periodic orbits, Stability, Analysis

Abstract

We consider a planar differential system $\dot{x}= P(x,y)$, $\dot{y} = Q(x,y)$, where $P$ and $Q$ are $\mathcal{C}^1$ functions in some open set $\mathcal{U} \subseteq \mathbb{R}^2$, and $\dot{}=\frac{d}{dt}$. Let $\gamma$ be a periodic orbit of the system in $\mathcal{U}$. Let $f(x,y): \mathcal{U} \subseteq \mathbb{R}^2 \to \mathbb{R}$ be a $\mathcal{C}^1$ function such that \[ P(x,y) \frac{\partial f}{\partial x}(x,y) + Q(x,y) \frac{\partial f}{\partial y} (x,y) = k(x,y) f(x,y), \] where $k(x,y)$ is a $\mathcal{C}^1$ function in $\mathcal{U}$ and $\gamma \subseteq \{(x,y) | f(x,y) = 0\}$. We assume that if $p \in \mathcal{U}$ is such that $f(p)=0$ and $\nabla f(p)=0$, then $p$ is a singular point. We prove that $\int_{0}^{T} (\frac{\partial P}{\partial x} + \frac{\partial Q}{\partial y})(\gamma(t)) dt= \int_0^{T} k(\gamma(t)) dt$, where $T>0$ is the period of $\gamma$. As an application, we take profit from this equality to show the hyperbolicity of the known algebraic limit cycles of quadratic systems., Comment: 22 pages, no figures

Published

2005

50. Complete hyperelliptic integrals of the first kind and their non-oscillation

Author

Iliya D. Iliev and Lubomir Gavrilov

Subjects

34C07, 3408, 70K05, Abelian integral, Applied Mathematics, General Mathematics, Mathematical analysis, Dynamical Systems (math.DS), Combinatorics, symbols.namesake, FOS: Mathematics, symbols, Real vector, Abelian group, Mathematics - Dynamical Systems, Hamiltonian (quantum mechanics), Open interval, Vector space, Mathematics

Abstract

Let P ( x ) P(x) be a real polynomial of degree 2 g + 1 2g+1 , H = y 2 + P ( x ) H=y^2+P(x) and δ ( h ) \delta (h) be an oval contained in the level set { H = h } \{H=h\} . We study complete Abelian integrals of the form \[ I ( h ) = ∫ δ ( h ) ( α 0 + α 1 x + … + α g − 1 x g − 1 ) d x y , h ∈ Σ , I(h)=\int _{\delta (h)} \frac {(\alpha _0+\alpha _1 x+\ldots + \alpha _{g-1}x^{g-1})dx}{y}, \;\;h\in \Sigma , \] where α i \alpha _i are real and Σ ⊂ R \Sigma \subset \mathbb {R} is a maximal open interval on which a continuous family of ovals { δ ( h ) } \{\delta (h)\} exists. We show that the g g -dimensional real vector space of these integrals is not Chebyshev in general: for any g > 1 g>1 , there are hyperelliptic Hamiltonians H H and continuous families of ovals δ ( h ) ⊂ { H = h } \delta (h)\subset \{H=h\} , h ∈ Σ h\in \Sigma , such that the Abelian integral I ( h ) I(h) can have at least [ 3 2 g ] − 1 [\frac 32g]-1 zeros in Σ \Sigma . Our main result is Theorem 1 in which we show that when g = 2 g=2 , exceptional families of ovals { δ ( h ) } \{\delta (h)\} exist, such that the corresponding vector space is still Chebyshev.

Published

2002