Application of a Generalized Frobenius-Perron Operator Scheme to Multivariate Nonlinear Dynamical Systems

Abstract The concept of generalized Frobenius-Perron operators is applied to multivariante nonlinear dynamical systems, and the associated generalized free energies are investigated. As important applications, diffusion-related free energies obtained from normally and superlinearly diffusive one-dimensional maps are discussed.

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Pynamical: Model and visualize discrete nonlinear dynamical systems, chaos, and fractals

10.31235/osf.io/g8nsf ◽

2018 ◽

Author(s):

Geoff Boeing

Keyword(s):

Dynamical Systems ◽

Phase Diagrams ◽

Nonlinear Dynamical Systems ◽

Nonlinear Models ◽

Logistic Map ◽

Three Dimensional ◽

Basins Of Attraction ◽

Nonlinear Dynamical ◽

One Dimensional ◽

One Dimensional Maps

Pynamical is an educational Python package for introducing the modeling, simulation, and visualization of discrete nonlinear dynamical systems and chaos, focusing on one-dimensional maps (such as the logistic map and the cubic map). Pynamical facilitates defining discrete one-dimensional nonlinear models as Python functions with just-in-time compilation for fast simulation. It comes packaged with the logistic map, the Singer map, and the cubic map predefined. The models may be run with a range of parameter values over a set of time steps, and the resulting numerical output is returned as a pandas DataFrame. Pynamical can then visualize this output in various ways, including with bifurcation diagrams, two-dimensional phase diagrams, three-dimensional phase diagrams, and cobweb plots. These visualizations enable simple qualitative assessments of system behavior including phase transitions, bifurcation points, attractors and limit cycles, basins of attraction, and fractals.

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UNIFORMITY AND SPATIAL CHAOS OF SPATIAL PHYSICS KINEMATIC SYSTEM

International Journal of Modern Physics B ◽

10.1142/s0217979210056918 ◽

2010 ◽

Vol 24 (28) ◽

pp. 5495-5503

Author(s):

SHUTANG LIU ◽

FUYAN SUN ◽

JIE SUN

Keyword(s):

Dynamical Systems ◽

Lattice Model ◽

Nonlinear Dynamical Systems ◽

Coupled Map Lattice ◽

Nonlinear Dynamical ◽

One Dimensional ◽

Uniform System ◽

Spatial Chaos ◽

Kinematic System ◽

Bifurcation Behavior

This article summarizes the uniformity law of spatial physics kinematic systems, and studies the chaos and bifurcation behavior of the uniform system in space. In particular, it also fully explains the relation among the uniform system, the coupled map lattice model which has attracted considerable interest currently, and one-dimensional nonlinear dynamical systems.

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MEASURING AND CONTROLLING THE CHAOTIC MOTION OF PROFITS

International Journal of Bifurcation and Chaos ◽

10.1142/s021812740902502x ◽

2009 ◽

Vol 19 (11) ◽

pp. 3593-3604 ◽

Cited By ~ 2

Author(s):

CRISTINA JANUÁRIO ◽

CLARA GRÁCIO ◽

DIANA A. MENDES ◽

JORGE DUARTE

Keyword(s):

Dynamical Systems ◽

Differential Equations ◽

Ordinary Differential Equations ◽

Nonlinear Dynamical Systems ◽

Control Technique ◽

Stable Steady State ◽

Chaotic Motions ◽

Nonlinear Dynamical ◽

Firm Model ◽

One Dimensional Maps

The study of economic systems has generated deep interest in exploring the complexity of chaotic motions in economy. Due to important developments in nonlinear dynamics, the last two decades have witnessed strong revival of interest in nonlinear endogenous business chaotic models. The inability to predict the behavior of dynamical systems in the presence of chaos suggests the application of chaos control methods, when we are more interested in obtaining regular behavior. In the present article, we study a specific economic model from the literature. More precisely, a system of three ordinary differential equations gather the variables of profits, reinvestments and financial flow of borrowings in the structure of a firm. Firstly, using results of symbolic dynamics, we characterize the topological entropy and the parameter space ordering of kneading sequences, associated with one-dimensional maps that reproduce significant aspects of the model dynamics. The analysis of the variation of this numerical invariant, in some realistic system parameter region, allows us to quantify and to distinguish different chaotic regimes. Finally, we show that complicated behavior arising from the chaotic firm model can be controlled without changing its original properties and the dynamics can be turned into the desired attracting time periodic motion (a stable steady state or into a regular cycle). The orbit stabilization is illustrated by the application of a feedback control technique initially developed by Romeiras et al. [1992]. This work provides another illustration of how our understanding of economic models can be enhanced by the theoretical and numerical investigation of nonlinear dynamical systems modeled by ordinary differential equations.

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Computation of the topological entropy in chaotic biophysical bursting models for excitable cells

Discrete Dynamics in Nature and Society ◽

10.1155/ddns/2006/60918 ◽

2006 ◽

Vol 2006 ◽

pp. 1-18 ◽

Cited By ~ 1

Author(s):

Jorge Duarte ◽

Luís Silva ◽

J. Sousa Ramos

Keyword(s):

Dynamical Systems ◽

Topological Entropy ◽

Nonlinear Dynamical Systems ◽

Dynamical Behavior ◽

Excitable Cells ◽

Physiological Models ◽

Nonlinear Dynamical ◽

Chaotic Bursting ◽

Oscillatory State ◽

One Dimensional Maps

One of the interesting complex behaviors in many cell membranes is bursting, in which a rapid oscillatory state alternates with phases of relative quiescence. Although there is an elegant interpretation of many experimental results in terms of nonlinear dynamical systems, the dynamics of bursting models is not completely described. In the present paper, we study the dynamical behavior of two specific three-variable models from the literature that replicate chaotic bursting. With results from symbolic dynamics, we characterize the topological entropy of one-dimensional maps that describe the salient dynamics on the attractors. The analysis of the variation of this important numerical invariant with the parameters of the systems allows us to quantify the complexity of the phenomenon and to distinguish different chaotic scenarios. This work provides an example of how our understanding of physiological models can be enhanced by the theory of dynamical systems.

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ON STRONG AND WEAK CHAOTIC PARTIAL SYNCHRONIZATION

International Journal of Bifurcation and Chaos ◽

10.1142/s0218127400000116 ◽

2000 ◽

Vol 10 (01) ◽

pp. 179-203 ◽

Cited By ~ 19

Author(s):

Yu. MAISTRENKO ◽

O. POPOVYCH ◽

M. HASLER

Keyword(s):

Nonlinear Dynamical Systems ◽

Chaotic Behavior ◽

Chaotic Synchronization ◽

State Variables ◽

Large Parameter ◽

Nonlinear Dynamical ◽

One Dimensional ◽

Rich Variety ◽

Parameter Ranges ◽

One Dimensional Maps

We study coupled nonlinear dynamical systems with chaotic behavior in the case when two or more (but not all) state variables synchronize, i.e. converge to each other asymptotically in time. It is shown that for symmetrical systems, such partial chaotic synchronization is usually only weak, whereas with nonsymmetrical coupling it can be strong in large parameter ranges. These facts are illustrated with systems of three coupled one-dimensional maps, for which a rich variety of different "partial chaotic synchronizing" phenomena takes place.

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