A Note on the Reproducibility of Chaos Simulation

Nazare, Thalita E.; Nepomuceno, Erivelton G.; Martins, Samir A. M.; Butusov, Denis N.

doi:10.3390/e22090953

Cited by 11 publications

(5 citation statements)

References 102 publications

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“…It is worth noting here that as far as the numerical evaluation of the chaotic system in the transmitter and receiver ends is concerned, there are instances where errors can arise, that may lead to degradation of the design. Examples can include round-off errors that arise when a different error tolerance is chosen between transmitter and receiver, or errors that arise when a different integration step is chosen or different numerical methods are used to solve the system; see for example, discussions in the recent works [52][53][54]. This is one of the main obstacles that have so far held up the possible commercialization of chaos-based secure communications.…”

Section: Discussionmentioning

confidence: 99%

A Novel Chaotic System with a Line Equilibrium: Analysis and Its Applications to Secure Communication and Random Bit Generation

Moysis

Volos

Stouboulos

et al. 2020

Telecom

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In this study, a novel two-parameter, three-dimensional chaotic system is constructed. The system has no linear terms and its equilibrium is a line, so it is a system with hidden attractors. The system is first studied by computation of its bifurcation diagrams and diagram of Lyapunov exponents. Then, the system is applied to two encryption related problems. First, the problem of secure communications is considered, using the symmetric chaos shift keying modulation method. Here, the states of the chaotic system are combined with a binary information signal in order to mask it, safely transmit it through a communication channel, and successfully reconstruct the information at the receiver end. In the second problem, the states of the system are utilized to design a simple rule to generate a bit sequence that possesses random properties, and is thus suitable for encryption related applications. For both applications, simulations are performed through Matlab to verify the soundness of the designs.

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Section: Discussionmentioning

confidence: 99%

A Novel Chaotic System with a Line Equilibrium: Analysis and Its Applications to Secure Communication and Random Bit Generation

Moysis

Volos

Stouboulos

et al. 2020

Telecom

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“…Thus, for a chaotic dynamical system, calculated trajectories of computer-generated simulations obtained by means of different numerical algorithms (with single/double precision) and different time steps are mostly quite different. Naturally, such kind of nonreplicability/unreliability of chaotic solution has brought plenty of heated debates on the credence of the numerical simulation of chaotic dynamical system [35], and someone even made an extremely pessimistic conclusion that "for chaotic systems, numerical convergence cannot be guaranteed forever" [47]. In addition, it has been recently reported that "shadowing solutions can be almost surely nonphysical", which "invalidates the argument that small perturbations in a chaotic system can only have a small impact on its statistical behavior" [4].…”

Section: Introductionmentioning

confidence: 99%

A Self-Adaptive Algorithm of the Clean Numerical Simulation (CNS) for Chaos

Liao¹

2023

AAMM

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The background numerical noise ε 0 is determined by the maximum of truncation error and round-off error. For a chaotic system, the numerical error ε(t) grows exponentially, say, ε(t) = ε 0 exp(κ t), where κ > 0 is the so-called noise-growing exponent. This is the reason why one can not gain a convergent simulation of chaotic systems in a long enough interval of time by means of traditional algorithms in double precision, since the background numerical noise ε 0 might stop decreasing because of the use of double precision. This restriction can be overcome by means of the clean numerical simulation (CNS), which can decrease the background numerical noise ε 0 to any required tiny level. A lot of successful applications show the novelty and validity of the CNS. In this paper, we further propose some strategies to greatly increase the computational efficiency of the CNS algorithms for chaotic dynamical systems. It is highly suggested to keep a balance between truncation error and round-off error and besides to progressively enlarge the background numerical noise ε 0 , since the exponentially increasing numerical noise ε(t) is much larger than it. Some examples are given to illustrate the validity of our strategies for the CNS.

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“…But in fact, it is not 100% natural chaos, it is degraded chaos due to computational limitations. 29–32 This can cause irreproducible and unreliable results, Nazaré et al 33 studied this topic.…”

Section: Introductionmentioning

confidence: 99%

“…[29][30][31][32] This can cause irreproducible and unreliable results, Nazare ét al. 33 studied this topic. As Ott et al 5 point out in their pioneering paper, any chaotic dynamic system can be controlled to be used by different purposes at different times.…”

Section: Introductionmentioning

confidence: 99%

Computational chaos control based on small perturbations for complex spectra simulation

et al. 2022

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In this paper, we propose to use a computational method of chaos control to simulate complex experimental spectra. This computational chaos control technique is based on the Ott–Grebogi–York (OGY) method. We chose the logistic map as the base mathematical model for the development of our work. For the numeric part, we created arbitrary precision algorithms to generate the solutions. This way, we completely eliminated any degradation of chaos from our results. These algorithms were also necessary for the proper perturbation process that the computational chaos control method requires. We control the chaos of the logistic map in two cases of Period 1 and one case of Period 2 to demonstrate that our control method works. The behavior of a complex experimental spectrum was taken and numerically simulated. The simulated spectrum was obtained by controlling the chaos of the logistic map in a variable way with the methods proposed in this work. Our results show that it is possible to simulate very complicated experimental spectra by computationally controlling the chaos of an equation unrelated to the experimental system.

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A Note on the Reproducibility of Chaos Simulation

Cited by 11 publications

References 102 publications

A Novel Chaotic System with a Line Equilibrium: Analysis and Its Applications to Secure Communication and Random Bit Generation

A Novel Chaotic System with a Line Equilibrium: Analysis and Its Applications to Secure Communication and Random Bit Generation

A Self-Adaptive Algorithm of the Clean Numerical Simulation (CNS) for Chaos

Computational chaos control based on small perturbations for complex spectra simulation

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