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      Detrended fluctuation analysis of earthquake data

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          Abstract

          The detrended fluctuation analysis (DFA) is extensively useful in stochastic processes to unveil the long-term correlation. Here, we apply the DFA to point processes that mimick earthquake data. The point processes are synthesized by a model similar to the Epidemic-Type Aftershock Sequence model, and we apply the DFA to time series \(N(t)\) of the point processes, where \(N(t)\) is the cumulative number of events up to time \(t\). Crossover phenomena are found in the DFA for these time series, and extensive numerical simulations suggest that the crossover phenomena are signatures of non-stationarity in the time series. We also find that the crossover time represents a characteristic time scale of the non-stationary process embedded in the time series. Therefore, the DFA for point processes is especially useful in extracting information of non-stationary processes when time series are superpositions of stationary and non-stationary signals. Furthermore, we apply the DFA to the cumulative number \(N(t)\) of real earthquakes in Japan, and we find a crossover phenomenon similar to that found for the synthesized data.

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          Author and article information

          Journal
          19 April 2021
          Article
          2104.09222
          58967e32-7153-40f3-b84d-6eef8e516416

          http://arxiv.org/licenses/nonexclusive-distrib/1.0/

          History
          Custom metadata
          9 pages, 5 figures
          physics.data-an physics.geo-ph

          Geophysics,Mathematical & Computational physics
          Geophysics, Mathematical & Computational physics

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