Deep learning applications for stellar parameter determination: II-application to the observed spectra of AFGK stars

Deep learning applications for stellar parameter determination: II-application to the observed spectra of AFGK stars

In this follow-up article, we investigate the use of convolutional neural network for deriving stellar parameters from observed spectra. Using hyperparameters determined previously, we have constructed a Neural Network architecture suitable for the derivation of , , , and . The network was constrain...

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Veröffentlicht in:Open astronomy 2023-01, Vol.32 (1), p.1031-1037
Hauptverfasser: Gebran, Marwan, Paletou, Frederic, Bentley, Ian, Brienza, Rose, Connick, Kathleen
Format: Artikel
Sprache:eng
Schlagworte:
Astrophysics
Data Analysis, Statistics and Probability
data analyzis methods
deep learning methods
fundamental parameter stars
Instrumentation and Methods for Astrophysic
methods
Physics
Sciences of the Universe
Solar and Stellar Astrophysics
spectroscopic techniques
statistical
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Zusammenfassung:In this follow-up article, we investigate the use of convolutional neural network for deriving stellar parameters from observed spectra. Using hyperparameters determined previously, we have constructed a Neural Network architecture suitable for the derivation of , , , and . The network was constrained by applying it to databases of AFGK synthetic spectra at different resolutions. Then, parameters of A stars from Polarbase, SOPHIE, and ELODIE databases are derived, as well as those of FGK stars from the spectroscopic survey of stars in the solar neighbourhood. The network model’s average accuracy on the stellar parameters is found to be as low as 80 K for , 0.06 dex for , 0.08 dex for , and 3 km/s for for AFGK stars.
ISSN:2543-6376
2543-6376
DOI:10.1515/astro-2022-0209