Representation learning for fast radio burst dynamic spectra

TL;DR

This paper explores unsupervised deep learning methods, including PCA and a novel IOB-augmented convolutional autoencoder, to analyze and interpret the complex dynamic spectra of fast radio bursts, revealing insights into their diversity and origins.

Contribution

It introduces an IOB-enhanced convolutional autoencoder for effective feature extraction and data compression of FRB spectra, advancing analysis of their morphological diversity.

Findings

PCA captures broad trends but struggles with complex structures.

IOB-CAE achieves high reconstruction accuracy and denoising.

Latent space analysis reveals a continuum of FRB morphologies.

Abstract

Fast radio bursts (FRBs) are millisecond-duration radio transients of extragalactic origin, with diverse time-frequency patterns and emission properties that require explanation. With one possible exception, FRBs are detected only in the radio, so analyzing their dynamic spectra is therefore crucial to disentangling the physical processes governing their generation and propagation. Furthermore, comparing FRB morphologies provides insights into possible differences among their progenitors and environments. This study applies unsupervised learning and deep learning techniques to investigate FRB dynamic spectra, focusing on two approaches: Principal Component Analysis (PCA) and a Convolutional Autoencoder (CAE) enhanced by an Information-Ordered Bottleneck (IOB) layer. PCA served as a computationally efficient baseline, capturing broad trends, identifying outliers, and providing valuable insights into large datasets. However, its linear nature limited its ability to reconstruct complex FRB structures. In contrast, the IOB-augmented CAE excelled at capturing intricate features, with high reconstruction accuracy and effective denoising at modest signal-to-noise ratios. The IOB layer's ability to prioritize relevant features enabled efficient data compression, preserving key morphological characteristics with minimal latent variables. When applied to real FRBs from CHIME, the IOB-CAE generalized effectively, revealing a latent space that highlighted the continuum of FRB morphologies and the potential for distinguishing intrinsic differences between burst types. This framework demonstrates that while FRBs may not naturally cluster into discrete groups, advanced representation learning techniques can uncover meaningful structures, offering new insights into the diversity and origins of these bursts.