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Main Authors: Li, Min-Yu, Qian, Sheng-Bang, Zhu, Li-Ying, Liao, Wen-Ping, Chang, Lin-Feng, Zhao, Er-Gang, Shi, Xiang-Dong, Li, Fu-Xing, Sun, Qi-Bin, Li, Ping
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2505.04067
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author Li, Min-Yu
Qian, Sheng-Bang
Zhu, Li-Ying
Liao, Wen-Ping
Chang, Lin-Feng
Zhao, Er-Gang
Shi, Xiang-Dong
Li, Fu-Xing
Sun, Qi-Bin
Li, Ping
author_facet Li, Min-Yu
Qian, Sheng-Bang
Zhu, Li-Ying
Liao, Wen-Ping
Chang, Lin-Feng
Zhao, Er-Gang
Shi, Xiang-Dong
Li, Fu-Xing
Sun, Qi-Bin
Li, Ping
contents Since the variety of their light curve morphologies, the vast majority of the known heartbeat stars (HBSs) have been discovered by manual inspection. Machine learning, which has already been successfully applied to the classification of variable stars based on light curves, offers another possibility for the automatic detection of HBSs. We propose a novel feature extraction approach for HBSs. First, the orbital frequencies are calculated automatically according to the Fourier spectra of the light curves. Then, the amplitudes of the first 100 harmonics are extracted. Finally, these harmonics are normalized as feature vectors of the light curve. A training data set of synthetic light curves is constructed using ELLC, and their features are fed into recurrent neural networks (RNNs) for supervised learning, with the expected output being the eccentricity of these light curves. The performance of the RNNs is evaluated using a test data set of synthetic light curves, achieving 95$\%$ accuracy. When applied to known HBSs from the OGLE, Kepler, and TESS surveys, the networks achieve an average accuracy of 86$\%$. This method successfully identifies four new HBSs within the eclipsing binary catalog of Kirk et al. The use of orbital harmonics as features for HBSs proves to be a practical approach that significantly reduces the computational cost of neural networks. RNNs show excellent performance in recognizing this type of time series data. This method not only allows efficient identification of HBSs but can also be extended to recognize other types of periodic variable stars.
format Preprint
id arxiv_https___arxiv_org_abs_2505_04067
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Heartbeat Stars Recognition Based on Recurrent Neural Networks: Method and Validation
Li, Min-Yu
Qian, Sheng-Bang
Zhu, Li-Ying
Liao, Wen-Ping
Chang, Lin-Feng
Zhao, Er-Gang
Shi, Xiang-Dong
Li, Fu-Xing
Sun, Qi-Bin
Li, Ping
Solar and Stellar Astrophysics
Instrumentation and Methods for Astrophysics
Since the variety of their light curve morphologies, the vast majority of the known heartbeat stars (HBSs) have been discovered by manual inspection. Machine learning, which has already been successfully applied to the classification of variable stars based on light curves, offers another possibility for the automatic detection of HBSs. We propose a novel feature extraction approach for HBSs. First, the orbital frequencies are calculated automatically according to the Fourier spectra of the light curves. Then, the amplitudes of the first 100 harmonics are extracted. Finally, these harmonics are normalized as feature vectors of the light curve. A training data set of synthetic light curves is constructed using ELLC, and their features are fed into recurrent neural networks (RNNs) for supervised learning, with the expected output being the eccentricity of these light curves. The performance of the RNNs is evaluated using a test data set of synthetic light curves, achieving 95$\%$ accuracy. When applied to known HBSs from the OGLE, Kepler, and TESS surveys, the networks achieve an average accuracy of 86$\%$. This method successfully identifies four new HBSs within the eclipsing binary catalog of Kirk et al. The use of orbital harmonics as features for HBSs proves to be a practical approach that significantly reduces the computational cost of neural networks. RNNs show excellent performance in recognizing this type of time series data. This method not only allows efficient identification of HBSs but can also be extended to recognize other types of periodic variable stars.
title Heartbeat Stars Recognition Based on Recurrent Neural Networks: Method and Validation
topic Solar and Stellar Astrophysics
Instrumentation and Methods for Astrophysics
url https://arxiv.org/abs/2505.04067