Towards the prediction of molecular parameters from astronomical emission lines using Neural Networks

Alejandro Barrientos; Jonathan Holdship; Mauricio Solar; Sergio Martín; Víctor M. Rivilla; Serena Viti; Jeff Mangum; Nanase Harada; Kazushi Sakamoto; Sébastien Muller; Kunihiko Tanaka; Yuki Yoshimura; Kouichiro Nakanishi; Rubén Herrero-Illana; Stefanie Mühle; Rebeca Aladro; Susanne Aalto; Christian Henkel; Pedro Humire

doi:10.1007/s10686-021-09786-w

Towards the prediction of molecular parameters from astronomical emission lines using Neural Networks

Alejandro Barrientos, Jonathan Holdship, Mauricio Solar, Sergio Martín, Víctor M. Rivilla, Serena Viti, Jeff Mangum, Nanase Harada, Kazushi Sakamoto, Sébastien Muller, Kunihiko Tanaka, Yuki Yoshimura, Kouichiro Nakanishi, Rubén Herrero-Illana, Stefanie Mühle, Rebeca Aladro, Susanne Aalto, Christian Henkel, Pedro Humire

Department of Physics

Research output: Contribution to journal › Article › peer-review

1 Citation (Scopus)

Abstract

Molecular astronomy is a field that is blooming in the era of large observatories such as the Atacama Large Millimeter/Submillimeter Array (ALMA). With modern, sensitive, and high spectral resolution radio telescopes like ALMA and the Square Kilometer Array, the size of the data cubes is rapidly escalating, generating a need for powerful automatic analysis tools. This work introduces MolPred, a pilot study to perform predictions of molecular parameters such as excitation temperature (T_ex) and column density (log(N)) from input spectra by the use of neural networks. We used as test cases the spectra of CO, HCO⁺, SiO and CH₃CN between 80 and 400 GHz. Training spectra were generated with MADCUBA, a state-of-the-art spectral analysis tool. Our algorithm was designed to allow the generation of predictions for multiple molecules in parallel. Using neural networks, we can predict the column density and excitation temperature of these molecules with a mean absolute error of 8.5% for CO, 4.1% for HCO⁺, 1.5% for SiO and 1.6% for CH₃CN. The prediction accuracy depends on the noise level, line saturation, and number of transitions. We performed predictions upon real ALMA data. The values predicted by our neural network for this real data differ by 13% from the MADCUBA values on average. Current limitations of our tool include not considering linewidth, source size, multiple velocity components, and line blending.

Original language	English
Pages (from-to)	157-182
Number of pages	26
Journal	Experimental Astronomy
Volume	52
Issue number	1-2
DOIs	https://doi.org/10.1007/s10686-021-09786-w
Publication status	Published - 2021 Oct

Keywords

ALCHEMI
MADCUBA
Machine learning
Molecular astronomy
Molecular parameters
Neural networks

ASJC Scopus subject areas

Astronomy and Astrophysics
Space and Planetary Science

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10.1007/s10686-021-09786-w

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Barrientos, A., Holdship, J., Solar, M., Martín, S., Rivilla, V. M., Viti, S., Mangum, J., Harada, N., Sakamoto, K., Muller, S., Tanaka, K., Yoshimura, Y., Nakanishi, K., Herrero-Illana, R., Mühle, S., Aladro, R., Aalto, S., Henkel, C., & Humire, P. (2021). Towards the prediction of molecular parameters from astronomical emission lines using Neural Networks. Experimental Astronomy, 52(1-2), 157-182. https://doi.org/10.1007/s10686-021-09786-w

Barrientos, A, Holdship, J, Solar, M, Martín, S, Rivilla, VM, Viti, S, Mangum, J, Harada, N, Sakamoto, K, Muller, S, Tanaka, K, Yoshimura, Y, Nakanishi, K, Herrero-Illana, R, Mühle, S, Aladro, R, Aalto, S, Henkel, C & Humire, P 2021, 'Towards the prediction of molecular parameters from astronomical emission lines using Neural Networks', Experimental Astronomy, vol. 52, no. 1-2, pp. 157-182. https://doi.org/10.1007/s10686-021-09786-w

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title = "Towards the prediction of molecular parameters from astronomical emission lines using Neural Networks",

abstract = "Molecular astronomy is a field that is blooming in the era of large observatories such as the Atacama Large Millimeter/Submillimeter Array (ALMA). With modern, sensitive, and high spectral resolution radio telescopes like ALMA and the Square Kilometer Array, the size of the data cubes is rapidly escalating, generating a need for powerful automatic analysis tools. This work introduces MolPred, a pilot study to perform predictions of molecular parameters such as excitation temperature (Tex) and column density (log(N)) from input spectra by the use of neural networks. We used as test cases the spectra of CO, HCO+, SiO and CH3CN between 80 and 400 GHz. Training spectra were generated with MADCUBA, a state-of-the-art spectral analysis tool. Our algorithm was designed to allow the generation of predictions for multiple molecules in parallel. Using neural networks, we can predict the column density and excitation temperature of these molecules with a mean absolute error of 8.5% for CO, 4.1% for HCO+, 1.5% for SiO and 1.6% for CH3CN. The prediction accuracy depends on the noise level, line saturation, and number of transitions. We performed predictions upon real ALMA data. The values predicted by our neural network for this real data differ by 13% from the MADCUBA values on average. Current limitations of our tool include not considering linewidth, source size, multiple velocity components, and line blending.",

keywords = "ALCHEMI, MADCUBA, Machine learning, Molecular astronomy, Molecular parameters, Neural networks",

author = "Alejandro Barrientos and Jonathan Holdship and Mauricio Solar and Sergio Mart{\'i}n and Rivilla, {V{\'i}ctor M.} and Serena Viti and Jeff Mangum and Nanase Harada and Kazushi Sakamoto and S{\'e}bastien Muller and Kunihiko Tanaka and Yuki Yoshimura and Kouichiro Nakanishi and Rub{\'e}n Herrero-Illana and Stefanie M{\"u}hle and Rebeca Aladro and Susanne Aalto and Christian Henkel and Pedro Humire",

note = "Funding Information: A.B. wishes to thank Dr. Diego Mardones for his contribution to the early stages of this work. Also, to acknowledge support from the Federico Santa Mar{\'i}a Technical University General Directorate for Research and Postgraduate Studies (DGIP). JH and SV are funded by the European Research Council (ERC) Advanced Grant MOPPEX 833460. V.M.R. acknowledges support from the Comunidad de Madrid through the Atracci{\'o}n de Talento Investigador Modalidad 1 (Doctores con experiencia) Grant (COOL: Cosmic Origins Of Life; 2019-T1/TIC-15379; PI: V.M. Rivilla). Publisher Copyright: {\textcopyright} 2021, The Author(s), under exclusive licence to Springer Nature B.V.",

year = "2021",

month = oct,

doi = "10.1007/s10686-021-09786-w",

language = "English",

volume = "52",

pages = "157--182",

journal = "Experimental Astronomy",

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T1 - Towards the prediction of molecular parameters from astronomical emission lines using Neural Networks

AU - Barrientos, Alejandro

AU - Holdship, Jonathan

AU - Solar, Mauricio

AU - Martín, Sergio

AU - Rivilla, Víctor M.

AU - Viti, Serena

AU - Mangum, Jeff

AU - Harada, Nanase

AU - Sakamoto, Kazushi

AU - Muller, Sébastien

AU - Tanaka, Kunihiko

AU - Yoshimura, Yuki

AU - Nakanishi, Kouichiro

AU - Herrero-Illana, Rubén

AU - Mühle, Stefanie

AU - Aladro, Rebeca

AU - Aalto, Susanne

AU - Henkel, Christian

AU - Humire, Pedro

N1 - Funding Information: A.B. wishes to thank Dr. Diego Mardones for his contribution to the early stages of this work. Also, to acknowledge support from the Federico Santa María Technical University General Directorate for Research and Postgraduate Studies (DGIP). JH and SV are funded by the European Research Council (ERC) Advanced Grant MOPPEX 833460. V.M.R. acknowledges support from the Comunidad de Madrid through the Atracción de Talento Investigador Modalidad 1 (Doctores con experiencia) Grant (COOL: Cosmic Origins Of Life; 2019-T1/TIC-15379; PI: V.M. Rivilla). Publisher Copyright: © 2021, The Author(s), under exclusive licence to Springer Nature B.V.

PY - 2021/10

Y1 - 2021/10

N2 - Molecular astronomy is a field that is blooming in the era of large observatories such as the Atacama Large Millimeter/Submillimeter Array (ALMA). With modern, sensitive, and high spectral resolution radio telescopes like ALMA and the Square Kilometer Array, the size of the data cubes is rapidly escalating, generating a need for powerful automatic analysis tools. This work introduces MolPred, a pilot study to perform predictions of molecular parameters such as excitation temperature (Tex) and column density (log(N)) from input spectra by the use of neural networks. We used as test cases the spectra of CO, HCO+, SiO and CH3CN between 80 and 400 GHz. Training spectra were generated with MADCUBA, a state-of-the-art spectral analysis tool. Our algorithm was designed to allow the generation of predictions for multiple molecules in parallel. Using neural networks, we can predict the column density and excitation temperature of these molecules with a mean absolute error of 8.5% for CO, 4.1% for HCO+, 1.5% for SiO and 1.6% for CH3CN. The prediction accuracy depends on the noise level, line saturation, and number of transitions. We performed predictions upon real ALMA data. The values predicted by our neural network for this real data differ by 13% from the MADCUBA values on average. Current limitations of our tool include not considering linewidth, source size, multiple velocity components, and line blending.

AB - Molecular astronomy is a field that is blooming in the era of large observatories such as the Atacama Large Millimeter/Submillimeter Array (ALMA). With modern, sensitive, and high spectral resolution radio telescopes like ALMA and the Square Kilometer Array, the size of the data cubes is rapidly escalating, generating a need for powerful automatic analysis tools. This work introduces MolPred, a pilot study to perform predictions of molecular parameters such as excitation temperature (Tex) and column density (log(N)) from input spectra by the use of neural networks. We used as test cases the spectra of CO, HCO+, SiO and CH3CN between 80 and 400 GHz. Training spectra were generated with MADCUBA, a state-of-the-art spectral analysis tool. Our algorithm was designed to allow the generation of predictions for multiple molecules in parallel. Using neural networks, we can predict the column density and excitation temperature of these molecules with a mean absolute error of 8.5% for CO, 4.1% for HCO+, 1.5% for SiO and 1.6% for CH3CN. The prediction accuracy depends on the noise level, line saturation, and number of transitions. We performed predictions upon real ALMA data. The values predicted by our neural network for this real data differ by 13% from the MADCUBA values on average. Current limitations of our tool include not considering linewidth, source size, multiple velocity components, and line blending.

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KW - MADCUBA

KW - Machine learning

KW - Molecular astronomy

KW - Molecular parameters

KW - Neural networks

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Towards the prediction of molecular parameters from astronomical emission lines using Neural Networks

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