Extreme Multistability and Its Incremental Integral Reconstruction in a Non-Autonomous Memcapacitive Oscillator

Chen, Bei; Cheng, Xinxin; Bao, Han; Chen, Mo; Xu, Quan

doi:10.3390/math10050754

Cited by 8 publications

(3 citation statements)

References 42 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…In systems with multi-metastable stages, the phase trajectory of the attractors depends on the initial conditions [31]. For specific conditions at low flux (Table 1), the bidimensional attractors are open cycles where the portraits of the phases do not overlap (Figures 4-6), which confirms the hypothesis that the system has a chaotic behavior.…”

Section: Chemicalsupporting

confidence: 59%

Chaos Synchronization of Two Györgyi–Field Systems for the Belousov–Zhabotinsky Chemical Reaction

Oancea¹,

Bodale

2022

Mathematics

View full text Add to dashboard Cite

Chemical reactions with oscillating behavior can present a chaos state in specific conditions. In this study, we analyzed the dynamic of the chaotic Belousov–Zhabotinsky (BZ) reaction using the Györgyi–Field model in order to identify the conditions of the chaos behavior. We studied the behavior of the reaction under different parameters that included both a low and high flux of chemical species. We performed our analysis of the flow regime in the conditions of an open reaction system, as this provides information about the behavior of the reaction over time. The proposed method for determining the favorable conditions for obtaining the state of chaos is based on the time evolution of the intermediate species and phase portraits. The synchronization of two Györgyi–Field systems based on the adaptive feedback method of control is presented in this work. The transient time until synchronization depends on the initial conditions of the two systems and on the strength of the controllers. Among the areas of interest for possible applications of the control method described in this paper, we can include identification of the reaction parameters and the extension to the other chaotic systems.

show abstract

Section: Chemicalsupporting

confidence: 59%

Chaos Synchronization of Two Györgyi–Field Systems for the Belousov–Zhabotinsky Chemical Reaction

Oancea¹,

Bodale

2022

Mathematics

View full text Add to dashboard Cite

show abstract

“…One can say that a dynamic system is called chaotic if solutions are found in a permanently bordered area B ⊂ n of the phase space and have the following fundamental characteristics: • Fourier transform (power spectrum) of any of the state variables is similar to white noise. This property indicates the appearance of a non-periodic chaotic trajectory [22].…”

Section: Lorenz Systemmentioning

confidence: 96%

Quality Evaluation for Reconstructing Chaotic Attractors

Frunzete

2022

Mathematics

View full text Add to dashboard Cite

Dynamical systems are used in various applications, and their simulation is related with the type of mathematical operations used in their construction. The quality of the system is evaluated in terms of reconstructing the system, starting from its final point to the beginning (initial conditions). Deciphering a message has to be without loss, and this paper will serve to choose the proper dynamical system to be used in chaos-based cryptography. The characterization of the chaotic attractors is the most important information in order to obtain the desired behavior. Here, observability and singularity are the main notions to be used for introducing an original term: quality observability index (q.o.i.). This is an original contribution for measuring the quality of the chaotic attractors. In this paper, the q.o.i. is defined and computed in order to confirm its usability.

show abstract

“…Considering a small network of identical all-to-all coupled phase oscillators, chaotic behaviour was found in networks of four or more phase oscillators with a single harmonic in their coupling function [11,12]. Many other types of neuron models and their firing activities have been studied in papers such as [13][14][15][16], where, specifically, the dynamics of a discrete memristive Rulkov neuron model which uses a memristor to describe the magnetic induction effects of the neuron and, respectively, a single neuron model with memristive synaptic weight, have been investigated.…”

Section: Introductionmentioning

confidence: 99%

Dynamics of a Reduced System Connected to the Investigation of an Infinite Network of Identical Theta Neurons

2022

View full text Add to dashboard Cite

We consider an infinite network of identical theta neurons, all-to-all coupled by instantaneous synapses. Using the Watanabe–Strogatz Ansatz, the mathematical model of this infinite network is reduced to a two-dimensional system of differential equations. We determine the number of equilibria of this reduced system with respect to two characteristic parameters. Furthermore, we discuss the stability properties of each equilibrium and the possible bifurcations that may take place. As a result, the occurrence of exotic higher codimension bifurcations involving a degenerate center is also unveiled. Numerical results are also presented to illustrate complex dynamic behaviour in the reduced system.

show abstract

Extreme Multistability and Its Incremental Integral Reconstruction in a Non-Autonomous Memcapacitive Oscillator

Cited by 8 publications

References 42 publications

Chaos Synchronization of Two Györgyi–Field Systems for the Belousov–Zhabotinsky Chemical Reaction

Chaos Synchronization of Two Györgyi–Field Systems for the Belousov–Zhabotinsky Chemical Reaction

Quality Evaluation for Reconstructing Chaotic Attractors

Dynamics of a Reduced System Connected to the Investigation of an Infinite Network of Identical Theta Neurons

Contact Info

Product

Resources

About