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This study introduces a unified framework combining empirical mode decomposition (EMD) and generalized fractal dimensions to analyze multiscale fluctuations in nonlinear time series. The method effectively characterizes complex dynamics across various systems, including real-world data.

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Area of Science:

  • Nonlinear Dynamics
  • Time Series Analysis
  • Complex Systems

Background:

  • Characterizing multiscale fluctuations in nonlinear and nonstationary time series is a key challenge in nonlinear sciences.
  • Existing methods often struggle to capture the complex, scale-dependent behavior inherent in such data.

Purpose of the Study:

  • To develop a unified analysis framework for characterizing multiscale fluctuations in nonlinear and nonstationary time series.
  • To integrate empirical mode decomposition (EMD) with generalized fractal dimensions for a comprehensive approach.

Main Methods:

  • The study combines empirical mode decomposition (EMD) to derive intrinsic mode functions (IMFs) representing local scale information.
  • Generalized fractal dimensions are then calculated from these IMFs to provide multiscale measures of system dynamics.
  • The framework is tested on diverse systems, including low- and high-dimensional deterministic models, fractional Brownian motion, and real-world time series.

Main Results:

  • The unified EMD-fractal dimension framework successfully characterizes multiscale properties across various dynamical systems.
  • The method demonstrates robustness against factors like noise, initial conditions, and time series length.
  • Application to paleoclimate and geomagnetic data confirms its utility for real-world time series analysis.

Conclusions:

  • The proposed formalism offers a powerful tool for dissecting the multiscale nature of fluctuations in complex systems.
  • This integrated approach enhances the understanding of nonlinear dynamics and nonstationarity in diverse scientific fields.
  • The framework's applicability to both simulated and real-world data highlights its broad potential.