Detection of Dynamical Regime Transitions with Lacunarity as a Multiscale Recurrence Quantification Measure

TL;DR

This paper introduces lacunarity as a new multiscale recurrence quantification measure that effectively detects dynamical regime transitions in complex systems, even with noisy or short data, surpassing traditional methods.

Contribution

The paper presents lacunarity as a novel recurrence quantifier that captures heterogeneity in recurrence plots without minimal line length constraints, broadening applicability.

Findings

Successfully detects dynamical transitions across multiple time scales.

Distinguishes stable and near blowout states in combustor data.

Performs well with noisy and short time series.

Abstract

We propose lacunarity as a novel recurrence quantification measure and illustrate its efficacy to detect dynamical regime transitions which are exhibited by many complex real-world systems. We carry out a recurrence plot based analysis for different paradigmatic systems and nonlinear empirical data in order to demonstrate the ability of our method to detect dynamical transitions ranging across different temporal scales. It succeeds to distinguish states of varying dynamical complexity in the presence of noise and non-stationarity, even when the time series is of short length. In contrast to traditional recurrence quantifiers, no specification of minimal line lengths is required and rather geometric features beyond linear structures in the recurrence plot can be accounted for. This makes lacunarity more broadly applicable as a recurrence quantification measure. Lacunarity is usually interpreted as a measure of heterogeneity or translational invariance of an arbitrary spatial pattern. In application to recurrence plots, it quantifies the degree of heterogenity in the temporal recurrence patterns at all relevant time scales. We demonstrate the potential of the proposed method when applied to empirical data, namely time series of acoustic pressure fluctuations from a turbulent combustor. Recurrence lacunarity captures both the rich variability in dynamical complexity of acoustic pressure fluctuations and shifting time scales encoded in the recurrence plots. Furthermore, it contributes to a better distinction between stable operation and near blowout states of combustors.