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Main Authors: Miller, Niall, Lucas, Philip, Sun, Yi, Guo, Zhen, Morris, Calum, Cooper, William
Format: Preprint
Published: 2024
Subjects:
Online Access:https://arxiv.org/abs/2406.08571
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author Miller, Niall
Lucas, Philip
Sun, Yi
Guo, Zhen
Morris, Calum
Cooper, William
author_facet Miller, Niall
Lucas, Philip
Sun, Yi
Guo, Zhen
Morris, Calum
Cooper, William
contents The ability to automatically and robustly self-verify periodicity present in time-series astronomical data is becoming more important as data sets rapidly increase in size. The age of large astronomical surveys has rendered manual inspection of time-series data less practical. Previous efforts in generating a false alarm probability to verify the periodicity of stars have been aimed towards the analysis of a constructed periodogram. However, these methods feature correlations with features that do not pertain to periodicity, such as light curve shape, slow trends and stochastic variability. The common assumption that photometric errors are Gaussian and well determined is also a limitation of analytic methods. We present a novel machine learning based technique which directly analyses the phase folded light curve for its false alarm probability. We show that the results of this method are largely insensitive to the shape of the light curve, and we establish minimum values for the number of data points and the amplitude to noise ratio.
format Preprint
id arxiv_https___arxiv_org_abs_2406_08571
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle The verification of periodicity with the use of recurrent neural networks
Miller, Niall
Lucas, Philip
Sun, Yi
Guo, Zhen
Morris, Calum
Cooper, William
Instrumentation and Methods for Astrophysics
The ability to automatically and robustly self-verify periodicity present in time-series astronomical data is becoming more important as data sets rapidly increase in size. The age of large astronomical surveys has rendered manual inspection of time-series data less practical. Previous efforts in generating a false alarm probability to verify the periodicity of stars have been aimed towards the analysis of a constructed periodogram. However, these methods feature correlations with features that do not pertain to periodicity, such as light curve shape, slow trends and stochastic variability. The common assumption that photometric errors are Gaussian and well determined is also a limitation of analytic methods. We present a novel machine learning based technique which directly analyses the phase folded light curve for its false alarm probability. We show that the results of this method are largely insensitive to the shape of the light curve, and we establish minimum values for the number of data points and the amplitude to noise ratio.
title The verification of periodicity with the use of recurrent neural networks
topic Instrumentation and Methods for Astrophysics
url https://arxiv.org/abs/2406.08571