Abstract
In this work, we address the following question: can we use modern, cutting-edge techniques conceived for the analysis of nonlinear non-stationary signals to measure scale-wise lags? To this scope, we propose a novel technique, called intrinsic mode cross correlation (IMXC) method, which leverages on the decomposition of nonlinear non-stationary signals by the multivariate fast iterative filtering (MvFIF) technique and the computation of a scale-by-scale cross correlation. We evaluate this technique on artificial signals (whose ground truth is known) and plasma density data provided by the Langmuir probes onboard the Swarm satellites. We show that this technique allows indeed to reconstruct the lag dependence on the involved spatio/temporal scales for the artificial dataset (even in the presence of high levels of noise) and to estimate them in a real-life signal. This can pave the way to future uses of this technique in contexts in which the causation chain can be hidden in a complex, multiscale coupling of the investigated features.
Highlights
The development of modern techniques for the analysis of multiscale systems has become of paramount importance, especially for the investigation of natural phenomena whose complexity manifests on a wide range of spatial and temporal scales
We leverage on the Multivariate Fast Iterative Filtering (MvFIF) [2] technique, being the multivariate implementation of the Fast Iterative Filtering (FIF) technique [4]
The proposed approach is used on plasma density data provided by the Langmuir probes onboard the Swarm satellites, addressing a simple case of interest
Summary
The development of modern techniques for the analysis of multiscale systems has become of paramount importance, especially for the investigation of natural phenomena whose complexity manifests on a wide range of spatial and temporal scales. This is the case of the Earth’s ionosphere, featured by a complex behavior due to its nonlinear coupling with the solar windmagnetosphere system from above and with the lower atmosphere from below Cross Correlation (IMXC spelled I-M-cross-C) method, for the scale-wise measurement of lags between two complex and non-stationary signals. The proposed approach is used on plasma density data provided by the Langmuir probes onboard the Swarm satellites, addressing a simple case of interest
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