Architectural Optimization and Feature Learning for High-Dimensional Time Series Datasets

TL;DR

This paper demonstrates how feature learning significantly improves the prediction of transient noise in gravitational wave detectors, outperforming fixed features and providing insights into noise origins.

Contribution

Introduces models that optimize features from high-dimensional data, reducing error rates by over 60%, and identifies key factors like sparsity and depth for successful high-dimensional learning.

Findings

Feature learning reduces error by over 60% compared to fixed features.

Sparsity and depth are crucial for effective high-dimensional modeling.

Learned features provide diagnostic insights into noise sources.

Abstract

As our ability to sense increases, we are experiencing a transition from data-poor problems, in which the central issue is a lack of relevant data, to data-rich problems, in which the central issue is to identify a few relevant features in a sea of observations. Motivated by applications in gravitational-wave astrophysics, we study the problem of predicting the presence of transient noise artifacts in a gravitational wave detector from a rich collection of measurements from the detector and its environment. We argue that feature learning--in which relevant features are optimized from data--is critical to achieving high accuracy. We introduce models that reduce the error rate by over 60% compared to the previous state of the art, which used fixed, hand-crafted features. Feature learning is useful not only because it improves performance on prediction tasks; the results provide valuable information about patterns associated with phenomena of interest that would otherwise be undiscoverable. In our application, features found to be associated with transient noise provide diagnostic information about its origin and suggest mitigation strategies. Learning in high-dimensional settings is challenging. Through experiments with a variety of architectures, we identify two key factors in successful models: sparsity, for selecting relevant variables within the high-dimensional observations; and depth, which confers flexibility for handling complex interactions and robustness with respect to temporal variations. We illustrate their significance through systematic experiments on real detector data. Our results provide experimental corroboration of common assumptions in the machine-learning community and have direct applicability to improving our ability to sense gravitational waves, as well as to many other problem settings with similarly high-dimensional, noisy, or partly irrelevant data.