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On the numerical simulation of propagation of micro-level inherent uncertainty for chaotic dynamic systems

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  • Liao, Shijun

Abstract

In this paper, an extremely accurate numerical algorithm, namely the “clean numerical simulation” (CNS), is proposed to accurately simulate the propagation of micro-level inherent physical uncertainty of chaotic dynamic systems. The chaotic Hamiltonian Hénon–Heiles system for motion of stars orbiting in a plane about the galactic center is used as an example to show its basic ideas and validity. Based on Taylor expansion at rather high-order and MP (multiple precision) data in very high accuracy, the CNS approach can provide reliable trajectories of the chaotic system in a finite interval t∈[0,Tc], together with an explicit estimation of the critical time Tc. Besides, the residual and round-off errors are verified and estimated carefully by means of different time-step Δt, different precision of data, and different order M of Taylor expansion. In this way, the numerical noises of the CNS can be reduced to a required level, i.e. the CNS is a rigorous algorithm. It is illustrated that, for the considered problem, the truncation and round-off errors of the CNS can be reduced even to the level of 10−1244 and 10−1000, respectively, so that the micro-level inherent physical uncertainty of the initial condition (in the level of 10−60) of the Hénon–Heiles system can be investigated accurately. It is found that, due to the sensitive dependence on initial condition (SDIC) of chaos, the micro-level inherent physical uncertainty of the position and velocity of a star transfers into the macroscopic randomness of motion. Thus, chaos might be a bridge from the micro-level inherent physical uncertainty to the macroscopic randomness in nature. This might provide us a new explanation to the SDIC of chaos from the physical viewpoint.

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  • Liao, Shijun, 2013. "On the numerical simulation of propagation of micro-level inherent uncertainty for chaotic dynamic systems," Chaos, Solitons & Fractals, Elsevier, vol. 47(C), pages 1-12.
    • Handle: RePEc:eee:chsofr:v:47:y:2013:i:c:p:1-12
    DOI: 10.1016/j.chaos.2012.11.009
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    References listed on IDEAS

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    1. P. Gaspard & M. E. Briggs & M. K. Francis & J. V. Sengers & R. W. Gammon & J. R. Dorfman & R. V. Calabrese, 1998. "Experimental evidence for microscopic chaos," Nature, Nature, vol. 394(6696), pages 865-868, August.
    2. Consoli, M. & Pluchino, A. & Rapisarda, A., 2011. "Basic randomness of nature and ether-drift experiments," Chaos, Solitons & Fractals, Elsevier, vol. 44(12), pages 1089-1099.
    3. Galatolo, Stefano & Hoyrup, Mathieu & Rojas, Cristóbal, 2012. "Statistical properties of dynamical systems – Simulation and abstract computation," Chaos, Solitons & Fractals, Elsevier, vol. 45(1), pages 1-14.
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    Cited by:

    1. Qin, Shijie & Liao, Shijun, 2020. "Influence of numerical noises on computer-generated simulation of spatio-temporal chaos," Chaos, Solitons & Fractals, Elsevier, vol. 136(C).
    2. Nepomuceno, Erivelton Geraldo & Mendes, Eduardo M.A.M., 2017. "On the analysis of pseudo-orbits of continuous chaotic nonlinear systems simulated using discretization schemes in a digital computer," Chaos, Solitons & Fractals, Elsevier, vol. 95(C), pages 21-32.
    3. De Micco, L. & Antonelli, M. & Larrondo, H.A., 2017. "Stochastic degradation of the fixed-point version of 2D-chaotic maps," Chaos, Solitons & Fractals, Elsevier, vol. 104(C), pages 477-484.

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