The article introduces a feature-based adaptation of conventional information-theoretic dependence detection methods to address the challenges in detecting long-timescale interactions between time series. The key insights are:
Traditional methods that operate directly on the raw time-series values can fail to capture underlying dependencies when interactions are mediated by statistical properties of the time series over longer timescales. This is due to the curse of dimensionality in estimating high-dimensional probability distributions from limited and noisy data.
The proposed feature-based approach extracts a candidate set of time-series features from sliding windows of the source time series and assesses their role in mediating a relationship to the target process. This reduces the dimensionality of the inference problem and can provide more interpretable insights into the nature of the interactions.
Through simulations of three different generative processes, the feature-based approach is shown to outperform the traditional signal-based approach, especially in challenging scenarios with short time-series lengths, high noise levels, and long interaction timescales.
The feature-based method introduces a new tool for inferring and interpreting feature-mediated interactions from time-series data, contributing to the broader landscape of quantitative analysis in complex systems research, with potential applications in various domains.
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