Cycle-StarNet: Bridging the Gap between Theory and Data by Leveraging Large Data Sets

O'Briain, Teaghan; Ting, Yuan-Sen; Fabbro, S.; Yi, Kwang Moo; Venn, Kim; Bialek, Spencer

doi:10.3847/1538-4357/abca96

Cited by 20 publications

(11 citation statements)

References 26 publications

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“…When teamed up with an optimization algorithm, the approach offers a fast way to analyze large volumes of spectroscopic data in the parameter space the neural network has been trained in. Even a higher level of data analysis is achieved with ML-based algorithms that employ the method of domain adaptation and offer a unique opportunity to improve theoretical models by learning from actual observations, as for example realized in the CYCLE-STARNET algorithm (O'Briain et al 2021).…”

Section: Introductionmentioning

confidence: 99%

Zeta-Payne: A Fully Automated Spectrum Analysis Algorithm for the Milky Way Mapper Program of the SDSS-V Survey

Straumit¹,

Tkachenko²,

Gebruers³

et al. 2022

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The Sloan Digital Sky Survey (SDSS) has recently initiated its fifth survey generation (SDSS-V), with a central focus on stellar spectroscopy. In particular, SDSS-V's Milky Way Mapper program will deliver multiepoch optical and near-infrared spectra for more than 5 × 106 stars across the entire sky, covering a large range in stellar mass, surface temperature, evolutionary stage, and age. About 10% of those spectra will be of hot stars of OBAF spectral types, for whose analysis no established survey pipelines exist. Here we present the spectral analysis algorithm, ZETA-PAYNE, developed specifically to obtain stellar labels from SDSS-V spectra of stars with these spectral types and drawing on machine-learning tools. We provide details of the algorithm training, its test on artificial spectra, and its validation on two control samples of real stars. Analysis with ZETA-PAYNE leads to only modest internal uncertainties in the near-IR with APOGEE (optical with BOSS): 3%–10% (1%–2%) for T eff, 5%–30% (5%–25%) for v sin i , 1.7–6.3 km s−1 (0.7–2.2 km s−1) for radial velocity, <0.1 dex (<0.05 dex) for log g , and 0.4–0.5 dex (0.1 dex) for [M/H] of the star, respectively. We find a good agreement between atmospheric parameters of OBAF-type stars when inferred from their high- and low-resolution optical spectra. For most stellar labels, the APOGEE spectra are (far) less informative than the BOSS spectra of these stars, while log g , v sin i , and [M/H] are in most cases too uncertain for meaningful astrophysical interpretation. This makes BOSS low-resolution optical spectra better for stellar labels of OBAF-type stars, unless the latter are subject to high levels of extinction.

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Section: Introductionmentioning

confidence: 99%

Zeta-Payne: A Fully Automated Spectrum Analysis Algorithm for the Milky Way Mapper Program of the SDSS-V Survey

Straumit¹,

Tkachenko²,

Gebruers³

et al. 2022

Self Cite

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“…Recently, this technique and its variants, such as a CNN, have become more and more popular in stellar spectroscopy for high computing performance. They have been extensively used in forward modeling (Ting et al 2019;Xiang et al 2019), backward modeling (Leung & Bovy 2019;Guiglion et al 2020;Wang et al 2020), and generative modeling (Yang et al 2021b;O'Briain et al 2021) of stellar spectra. In this work, we use a CNN discriminative model to cope with the binary classification problem.…”

Section: The Discriminative Modelmentioning

confidence: 99%

The Spectroscopic Binaries from the LAMOST Medium-resolution Survey. I. Searching for Double-lined Spectroscopic Binaries with a Convolutional Neural Network

Zhang

Jing

Yang

et al. 2022

ApJS

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We developed a convolutional neural network model to distinguish the double-lined spectroscopic binaries (SB2s) from others based on single-exposure medium-resolution spectra (R ∼ 7500). The training set consists of a large set of mock spectra of single stars and binaries synthesized based on the MIST stellar evolutionary model and ATLAS9 atmospheric model. Our model reaches a novel theoretic false-positive rate by adding a proper penalty on the negative sample (e.g., 0.12% and 0.16% for the blue/red arm when the penalty parameter Λ = 16). Tests show that the performance is as expected and favors FGK-type main-sequence (MS) binaries with high mass ratio (q ≥ 0.7) and large radial velocity separation (Δv ≥ 50 km s−1). Although the real false-positive rate cannot be estimated reliably, validating on eclipsing binaries identified from Kepler light curves indicates that our model predicts low binary probabilities at eclipsing phases (0, 0.5, and 1.0) as expected. The color–magnitude diagram also helps illustrate its feasibility and capability of identifying FGK MS binaries from spectra. We conclude that this model is reasonably reliable and can provide an automatic approach to identify SB2s with period ≲10 days. This work yields a catalog of binary probabilities for over 5 million spectra of 1 million sources from the LAMOST medium-resolution survey (MRS) and a catalog of 2198 SB2 candidates whose physical properties will be analyzed in a follow-up paper. Data products are made publicly available online, as well as our Github website.

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“…But more generally, the statistical description of the distribution of spectra through Mendis has a wide range of applications beyond the few case studies explored here. For example, Mendis can serve as a bridge for supervised and unsupervised learning -the learned distribution can serve as the prior distribution for domain adaption to close the model-data synthetic gap (O'Briain et al, 2021). Additionally, the distribution can serve as the basis for semi-supervision and few-shots learning with a limited number of stars with high-fidelity labels.…”

Section: Prospects and Future Directionsmentioning

confidence: 99%

Unsupervised Learning for Stellar Spectra with Deep Normalizing Flows

Ciucă¹,

Ting²

2022

Preprint

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Stellar spectra encode detailed information about the stars. However, most machine learning approaches in stellar spectroscopy focus on supervised learning. We introduce Mendis, an unsupervised learning method, which adopts normalizing flows consisting of Neural Spline Flows and GLOW to describe the complex distribution of spectral space. A key advantage of Mendis is that we can describe the conditional distribution of spectra, conditioning on stellar parameters, to unveil the underlying structures of the spectra further. In particular, our study demonstrates that Mendis can robustly capture the pixel correlations in the spectra leading to the possibility of detecting unknown atomic transitions from stellar spectra. The probabilistic nature of Mendis also enables a rigorous determination of outliers in extensive spectroscopic surveys without the need to measure elemental abundances through existing analysis pipelines beforehand.

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Cycle-StarNet: Bridging the Gap between Theory and Data by Leveraging Large Data Sets

Cited by 20 publications

References 26 publications

Zeta-Payne: A Fully Automated Spectrum Analysis Algorithm for the Milky Way Mapper Program of the SDSS-V Survey

Zeta-Payne: A Fully Automated Spectrum Analysis Algorithm for the Milky Way Mapper Program of the SDSS-V Survey

The Spectroscopic Binaries from the LAMOST Medium-resolution Survey. I. Searching for Double-lined Spectroscopic Binaries with a Convolutional Neural Network

Unsupervised Learning for Stellar Spectra with Deep Normalizing Flows

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