An application of deep learning in the analysis of stellar spectra

Fabbro, S.; Venn, Kim A.; O'Briain, Teaghan; Bialek, Spencer; Kielty, Collin; Jahandar, Farbod; Monty, Stephanie

doi:10.1093/mnras/stx3298

Cited by 96 publications

(102 citation statements)

References 80 publications

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“…Artificial neural network (ANN) methods were firstly adopted to determine stellar atmospheric parameters by Bailer- Jones et al (1997), and rejuvenated recently because of development of new training techniques and hardware. Inspired by the successful application of con- volutional neural networks (CNN) to APOGEE spectra (Fabbro et al 2018;Leung & Bovy 2019), we design a specific CNN structure for transferring stellar labels from APOGEE-payne catalog to LAMOST-II MRS spectra.…”

Section: Methodsmentioning

confidence: 99%

“…Researchers made efforts on machine learning in stellar parameter estimation, such as The Cannon (Ness et al 2015;Casey et al 2016), The Payne , StarNet (Fabbro et al 2018), AstroNN (Leung & Bovy 2019) and GSN (Wang et al 2019a), and most of them employ artificial neural networks for building regression map relationship. These methods depend on training and test sets usually called reference sets, and the more complete the parameter space covers, the more information can be obtained by the model training.…”

Section: Introductionmentioning

confidence: 99%

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SPCANet: Stellar Parameters and Chemical Abundances Network for LAMOST-II Medium Resolution Survey

Wang

Luo

Chen³

et al. 2020

ApJ

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The fundamental stellar atmospheric parameters (T eff and log g) and 13 chemical abundances are derived for medium-resolution spectroscopy from LAMOST Medium-Resolution Survey (MRS) data sets with a deep-learning method. The neural networks we designed, named as SPCANet, precisely map LAMOST MRS spectra to stellar parameters and chemical abundances. The stellar labels derived by SPCANet are with precisions of 119 K for T eff and 0.17 dex for log g. The abundance precision of 11 elements including [[Fe/H], and [Ni/H] are 0.06∼0.12 dex, while of [Cu/H] is 0.19 dex. These precisions can be reached even for spectra with signal-to-noise as low as 10. The results of SPCANet are consistent with those from other surveys such as APOGEE, GALAH and RAVE, and are also validated with the previous literature values including clusters and field stars. The catalog of the estimated parameters is available at http://paperdata.china-vo.org/LAMOST/MRS parameters elements.csv.

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Section: Methodsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

SPCANet: Stellar Parameters and Chemical Abundances Network for LAMOST-II Medium Resolution Survey

Wang

Luo

Chen³

et al. 2020

ApJ

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“…m and c denote the slope and intercept of the linear fit. Another parameter that we use to evaluate the goodness of prediction is R 2 -Score (Steel & Torrie 1960;Glantz 1990;Draper 1998), also referred to as coefficient of determination, which indicates the proportion of variance in the predicted labels governed by the expected labels. R 2 -Score can take the values in the range 0-1, and is defined as:…”

Section: Machine Learning: Methods and Resultsmentioning

confidence: 99%

“…In this work, we apply shallow neural networks (NNs) as well as deep convolutional neural networks to study optical stellar spectra in detail and investigate whether using deeper networks of convolutional layers can significantly reduce the error and accuracy achieved in the stellar spectral classification. Deep learning frameworks (Hinton & Salakhutdinov 2006;Bengio 2009;Zeiler & Fergus 2013) have been used in the astronomical domain for various applications like galaxy morphology prediction (Dieleman et al 2015), classification of variable stars based on their light curves (Mahabal et al 2017), estimating atmospheric parameters using stellar spectra (Fabbro et al 2018), detecting bar structures in galaxy images (Abraham et al 2018), classifying galaxy morphologies at radio wavelengths (Wu et al 2019) etc. However, all these problems require a large sample for supervised training of the network.…”

Section: Introductionmentioning

confidence: 99%

Application of convolutional neural networks for stellar spectral classification

Sharma

Kembhavi

et al. 2019

Monthly Notices of the Royal Astronomical Society

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Due to the ever-expanding volume of observed spectroscopic data from surveys such as SDSS and LAMOST, it has become important to apply artificial intelligence (AI) techniques for analysing stellar spectra to solve spectral classification and regression problems like the determination of stellar atmospheric parameters T eff , log g, and [Fe/H]. We propose an automated approach for the classification of stellar spectra in the optical region using Convolutional Neural Networks. Traditional machine learning (ML) methods with "shallow" architecture (usually up to 2 hidden layers) have been trained for these purposes in the past. However, deep learning methods with a larger number of hidden layers allow the use of finer details in the spectrum which results in improved accuracy and better generalisation. Studying finer spectral signatures also enables us to determine accurate differential stellar parameters and find rare objects. We examine various machine and deep learning algorithms like Artificial Neural Networks (ANN), Random Forest (RF), and Convolutional Neural Network (CNN) to classify stellar spectra using the Jacoby Atlas, ELODIE and MILES spectral libraries as training samples. We test the performance of the trained networks on the Indo-U.S. Library of Coudé Feed Stellar Spectra (CFLIB). We show that using convolutional neural networks, we are able to lower the error up to 1.23 spectral sub-classes as compared to that of 2 sub-classes achieved in the past studies with ML approach. We further apply the trained model to classify stellar spectra retrieved from the SDSS database with SNR>20.

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“…Convolutional Neural Networks (CNNs) 3 are growing in popularity in many areas of Astronomy, typically as a means of analysing 2D image data (e.g. Tuccillo et al 2017;Petrillo et al 2017), and have been shown to perform remarkably well, with prediction accuracies in classification tasks approaching human level (Flamary 2016;Fabbro et al 2018).…”

Section: Convolutional Neural Networkmentioning

confidence: 99%

Learning the relationship between galaxies spectra and their star formation histories using convolutional neural networks and cosmological simulations

Lovell

Acquaviva

Thomas

et al. 2019

Monthly Notices of the Royal Astronomical Society

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We present a new method for inferring galaxy star formation histories (SFH) using machine learning methods coupled with two cosmological hydrodynamic simulations. We train Convolutional Neural Networks to learn the relationship between synthetic galaxy spectra and high resolution SFHs from the EAGLE and Illustris models. To evaluate our SFH reconstruction we use Symmetric Mean Absolute Percentage Error (SMAPE), which acts as a true percentage error in the low-error regime. On dustattenuated spectra we achieve high test accuracy (median SMAPE = 10.5%). Including the effects of simulated observational noise increases the error (12.5%), however this is alleviated by including multiple realisations of the noise, which increases the training set size and reduces overfitting (10.9%). We also make estimates for the observational and modelling errors. To further evaluate the generalisation properties we apply models trained on one simulation to spectra from the other, which leads to only a small increase in the error (median SMAPE ∼ 15%). We apply each trained model to SDSS DR7 spectra, and find smoother histories than in the VESPA catalogue. This new approach complements the results of existing SED fitting techniques, providing star formation histories directly motivated by the results of the latest cosmological simulations.

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An application of deep learning in the analysis of stellar spectra

Cited by 96 publications

References 80 publications

SPCANet: Stellar Parameters and Chemical Abundances Network for LAMOST-II Medium Resolution Survey

SPCANet: Stellar Parameters and Chemical Abundances Network for LAMOST-II Medium Resolution Survey

Application of convolutional neural networks for stellar spectral classification

Learning the relationship between galaxies spectra and their star formation histories using convolutional neural networks and cosmological simulations

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