FREQUENCY SWEEP METHOD FOR STUDY OF PERIOD-DOUBLING BIFURCATION AND CHAOTIC BEHAVIOR

AbstractChaotic phenomena are observed in several practical and scientific fields; however, the chaos is harmful to systems as they can lead them to be unstable. Consequently, the purpose of this study is to analyze the bifurcation of permanent magnet direct current (PMDC) motor and develop a controller that can suppress chaotic behavior resulted from parameter variation such as the loading effect. The nonlinear behaviors of PMDC motors were investigated by time-domain waveform, phase portrait, and Floquet theory. By varying the load torque, a period-doubling bifurcation appeared which in turn led to chaotic behavior in the system. So, a fuzzy logic controller and developing the Floquet theory techniques are applied to eliminate the bifurcation and the chaos effects. The controller is used to enhance the performance of the system by getting a faster response without overshoot or oscillation, moreover, tends to reduce the steady-state error while maintaining its stability. The simulation results emphasize that fuzzy control provides better performance than that obtained from the other controller.

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Dynamical behavior of nonlinear wave solutions of the generalized Newell–Whitehead–Segel equation

International Journal of Modern Physics C ◽

10.1142/s012918312050059x ◽

2020 ◽

Vol 31 (04) ◽

pp. 2050059

Author(s):

Asit Saha ◽

Amiya Das

Keyword(s):

Nonlinear Wave ◽

Chaotic Behavior ◽

Dynamical Behavior ◽

Period Doubling ◽

Period Doubling Bifurcation ◽

Phase Portraits ◽

Phase Plane Analysis ◽

Linear Coefficient ◽

Wave Solutions ◽

Nonlinear Wave Solutions

Dynamical behavior of nonlinear wave solutions of the perturbed and unperturbed generalized Newell–Whitehead–Segel (GNWS) equation is studied via analytical and computational approaches for the first time in the literature. Bifurcation of phase portraits of the unperturbed GNWS equation is dispensed using phase plane analysis through symbolic computation and it shows stable oscillation of the traveling waves. Chaotic behavior of the perturbed GNWS equation is obtained by applying different computational tools, like phase plot, time series plot, Poincare section, bifurcation diagram and Lyapunov exponent. A period-doubling bifurcation behavior to chaotic behavior is shown for the perturbed GNWS equation and again it shows chaotic to periodic motion through inverse period-doubling bifurcation. The perturbed GNWS equation also shows chaotic motion through a sequence of periodic motions (period-1, period-3 and period-5) depending on the variation of the parameter of linear coefficient. Thus, the parameter of linear coefficient plays the role of a controlling parameter in the chaotic dynamics of the perturbed GNWS equation.

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CONNECTING PERIOD-DOUBLING CASCADES TO CHAOS

International Journal of Bifurcation and Chaos ◽

10.1142/s0218127412500228 ◽

2012 ◽

Vol 22 (02) ◽

pp. 1250022 ◽

Cited By ~ 25

Author(s):

EVELYN SANDER ◽

JAMES A. YORKE

Keyword(s):

Periodic Orbit ◽

Periodic Orbits ◽

Chaotic Behavior ◽

Period Doubling ◽

Duffing Equation ◽

Period Doubling Bifurcation ◽

Bifurcation Diagrams ◽

The Third ◽

Infinite Collection

The appearance of infinitely-many period-doubling cascades is one of the most prominent features observed in the study of maps depending on a parameter. They are associated with chaotic behavior, since bifurcation diagrams of a map with a parameter often reveal a complicated intermingling of period-doubling cascades and chaos. Period doubling can be studied at three levels of complexity. The first is an individual period-doubling bifurcation. The second is an infinite collection of period doublings that are connected together by periodic orbits in a pattern called a cascade. It was first described by Myrberg and later in more detail by Feigenbaum. The third involves infinitely many cascades and a parameter value μ2 of the map at which there is chaos. We show that often virtually all (i.e. all but finitely many) "regular" periodic orbits at μ2 are each connected to exactly one cascade by a path of regular periodic orbits; and virtually all cascades are either paired — connected to exactly one other cascade, or solitary — connected to exactly one regular periodic orbit at μ2. The solitary cascades are robust to large perturbations. Hence the investigation of infinitely many cascades is essentially reduced to studying the regular periodic orbits of F(μ2, ⋅). Examples discussed include the forced-damped pendulum and the double-well Duffing equation.

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Bifurcation analysis and chaos control of a second-order exponential difference equation

Filomat ◽

10.2298/fil1915003d ◽

2019 ◽

Vol 33 (15) ◽

pp. 5003-5022 ◽

Cited By ~ 2

Author(s):

Q. Din ◽

E.M. Elabbasy ◽

A.A. Elsadany ◽

S. Ibrahim

Keyword(s):

Difference Equation ◽

Chaos Control ◽

Control Method ◽

Chaotic Behavior ◽

Initial Conditions ◽

Period Doubling ◽

Second Order ◽

Period Doubling Bifurcation ◽

Positive Real ◽

Second Order Difference Equation

The aim of this article is to study the local stability of equilibria, investigation related to the parametric conditions for transcritical bifurcation, period-doubling bifurcation and Neimark-Sacker bifurcation of the following second-order difference equation xn+1 = ?xn + ?xn-1 exp(-?xn-1) where the initial conditions x-1, x0 are the arbitrary positive real numbers and ?,? and ? are positive constants. Moreover, chaos control method is implemented for controlling chaotic behavior under the influence of Neimark-Sacker bifurcation and period-doubling bifurcation. Numerical simulations are provided to show effectiveness of theoretical discussion.

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The Effect of Convection in Nonlinear One-Zone Stellar Models

International Astronomical Union Colloquium ◽

10.1017/s0252921100014457 ◽

1993 ◽

Vol 134 ◽

pp. 355-358

Author(s):

M. Saitou

Keyword(s):

Limit Cycle ◽

Chaotic Behavior ◽

Period Doubling ◽

Variable Stars ◽

Period Doubling Bifurcation ◽

The Other ◽

Other Hand ◽

Pulsating Variable Stars ◽

Stellar Models

AbstractWe study the convective nonlinear one-zone models of the pulsating variable stars. In the small convective case, the solution shows chaotic behavior through the period doubling bifurcation as the temperature is lower although the temperature at which the chaos appears is lower than in the case of no convection. On the other hand, in the strong convective case, the solution only shows period-one limit cycle.

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A quasi-analytical approach to period-doubling bifurcation computation and prediction

1999 European Control Conference (ECC) ◽

10.23919/ecc.1999.7099331 ◽

1999 ◽

Cited By ~ 1

Author(s):

Daniel W. Berns ◽

Jorge L. Moiola ◽

Guanrong Chen

Keyword(s):

Analytical Approach ◽

Period Doubling ◽

Period Doubling Bifurcation

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Dynamics, Synchronization and Electronic Implementations of a New Lorenz-like Chaotic System with Nonhyperbolic Equilibria

International Journal of Bifurcation and Chaos ◽

10.1142/s0218127419501979 ◽

2019 ◽

Vol 29 (14) ◽

pp. 1950197 ◽

Cited By ~ 2

Author(s):

P. D. Kamdem Kuate ◽

Qiang Lai ◽

Hilaire Fotsin

Keyword(s):

Chaotic System ◽

Chaotic Systems ◽

Lorenz System ◽

Chaotic Behavior ◽

Piecewise Linear ◽

Period Doubling ◽

Adaptive Synchronization ◽

The Novel ◽

Algebraic Equations ◽

The Lorenz System

The Lorenz system has attracted increasing attention on the issue of its simplification in order to produce the simplest three-dimensional chaotic systems suitable for secure information processing. Meanwhile, Sprott’s work on elegant chaos has revealed a set of 19 chaotic systems all described by simple algebraic equations. This paper presents a new piecewise-linear chaotic system emerging from the simplification of the Lorenz system combined with the elegance of Sprott systems. Unlike the majority, the new system is a non-Shilnikov chaotic system with two nonhyperbolic equilibria. It is multiplier-free, variable-boostable and exclusively based on absolute value and signum nonlinearities. The use of familiar tools such as Lyapunov exponents spectra, bifurcation diagrams, frequency power spectra as well as Poincaré map help to demonstrate its chaotic behavior. The novel system exhibits inverse period doubling bifurcations and multistability. It has only five terms, one bifurcation parameter and a total amplitude controller. These features allow a simple and low cost electronic implementation. The adaptive synchronization of the novel system is investigated and the corresponding electronic circuit is presented to confirm its feasibility.

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Complex dynamics and coexistence of period-doubling and period-halving bifurcations in an integrated pest management model with nonlinear impulsive control

Advances in Difference Equations ◽

10.1186/s13662-020-02971-9 ◽

2020 ◽

Vol 2020 (1) ◽

Author(s):

Changtong Li ◽

Sanyi Tang ◽

Robert A. Cheke

Keyword(s):

Periodic Solution ◽

Integrated Pest Management ◽

Pest Management ◽

Pest Control ◽

Impulsive Control ◽

Period Doubling ◽

Dynamical Behaviour ◽

Period Doubling Bifurcation ◽

Predator Prey ◽

Predator Prey Model

Abstract An expectation for optimal integrated pest management is that the instantaneous numbers of natural enemies released should depend on the densities of both pest and natural enemy in the field. For this, a generalised predator–prey model with nonlinear impulsive control tactics is proposed and its dynamics is investigated. The threshold conditions for the global stability of the pest-free periodic solution are obtained based on the Floquet theorem and analytic methods. Also, the sufficient conditions for permanence are given. Additionally, the problem of finding a nontrivial periodic solution is confirmed by showing the existence of a nontrivial fixed point of the model’s stroboscopic map determined by a time snapshot equal to the common impulsive period. In order to address the effects of nonlinear pulse control on the dynamics and success of pest control, a predator–prey model incorporating the Holling type II functional response function as an example is investigated. Finally, numerical simulations show that the proposed model has very complex dynamical behaviour, including period-doubling bifurcation, chaotic solutions, chaos crisis, period-halving bifurcations and periodic windows. Moreover, there exists an interesting phenomenon whereby period-doubling bifurcation and period-halving bifurcation always coexist when nonlinear impulsive controls are adopted, which makes the dynamical behaviour of the model more complicated, resulting in difficulties when designing successful pest control strategies.

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