Investigation of Complexity Dynamics in a DC Glow Discharge Magnetized Plasma Using Recurrence Quantification Analysis

World Academy of Science, Engineering and Technology, International Journal of Physical and Mathematical Sciences Pub Date : 2016-06-01 DOI:10.1063/1.4953903

V. Mitra, B. Sarma, A. Sarma

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引用次数: 6

Abstract

Recurrence is an ubiquitous feature which provides deep insights into the dynamics of real dynamical systems. A suitable tool for investigating recurrences is recurrence quantification analysis (RQA). It allows, e.g., the detection of regime transitions with respect to varying control parameters. We investigate the complexity of different coexisting nonlinear dynamical regimes of the plasma floating potential fluctuations at different magnetic fields and discharge voltages by using recurrence quantification variables, in particular, DET, Lmax, and Entropy. The recurrence analysis reveals that the predictability of the system strongly depends on discharge voltage. Furthermore, the persistent behaviour of the plasma time series is characterized by the Detrended fluctuation analysis technique to explore the complexity in terms of long range correlation. The enhancement of the discharge voltage at constant magnetic field increases the nonlinear correlations; hence, the complexity of the system decreases, whic...

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用递归量化分析研究直流辉光放电磁化等离子体的复杂性动力学

递归是一个普遍存在的特征，它为实际动力系统的动力学提供了深刻的见解。研究递归的合适工具是递归量化分析(RQA)。例如，它允许检测相对于不同控制参数的状态转变。利用递归量化变量DET、Lmax和熵，研究了不同磁场和放电电压下等离子体浮势波动的非线性动力学机制的复杂性。递归分析表明，系统的可预测性在很大程度上取决于放电电压。此外，利用去趋势波动分析技术对等离子体时间序列的持续行为进行表征，以探索其长期相关的复杂性。恒磁场下放电电压的增大使非线性相关系数增大;因此，系统的复杂性降低了，这……

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World Academy of Science, Engineering and Technology, International Journal of Physical and Mathematical Sciences

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