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Main Authors: Kim, Young-Lo, Hook, Isobel, Milligan, Andrew, Galbany, Lluís, Sollerman, Jesper, Burgaz, Umut, Dimitriadis, Georgios, Fremling, Christoffer, Johansson, Joel, Müller-Bravo, Tomás E., Neill, James D., Nordin, Jakob, Nugent, Peter, Qi, Yu-Jing, Rosnet, Philippe, Sharma, Yashvi
Format: Preprint
Published: 2024
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Online Access:https://arxiv.org/abs/2410.10963
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author Kim, Young-Lo
Hook, Isobel
Milligan, Andrew
Galbany, Lluís
Sollerman, Jesper
Burgaz, Umut
Dimitriadis, Georgios
Fremling, Christoffer
Johansson, Joel
Müller-Bravo, Tomás E.
Neill, James D.
Nordin, Jakob
Nugent, Peter
Qi, Yu-Jing
Rosnet, Philippe
Sharma, Yashvi
author_facet Kim, Young-Lo
Hook, Isobel
Milligan, Andrew
Galbany, Lluís
Sollerman, Jesper
Burgaz, Umut
Dimitriadis, Georgios
Fremling, Christoffer
Johansson, Joel
Müller-Bravo, Tomás E.
Neill, James D.
Nordin, Jakob
Nugent, Peter
Qi, Yu-Jing
Rosnet, Philippe
Sharma, Yashvi
contents Accurate classification of transients obtained from spectroscopic data are important to understand their nature and discover new classes of astronomical objects. For supernovae (SNe), SNID, NGSF (a Python version of SuperFit), and DASH are widely used in the community. Each tool provides its own metric to help determine classification, such as rlap of SNID, chi2/dof of NGSF, and Probability of DASH. However, we do not know how accurate these tools are, and they have not been tested with a large homogeneous dataset. Thus, in this work, we study the accuracy of these spectral classification tools using 4,646 SEDMachine spectra, which have accurate classifications obtained from the Zwicky Transient Facility Bright Transient Survey (BTS). Comparing our classifications with those from BTS, we have tested the classification accuracy in various ways. We find that NGSF has the best performance (overall Accuracy 87.6% when samples are split into SNe Ia and Non-Ia types), while SNID and DASH have similar performance with overall Accuracy of 79.3% and 76.2%, respectively. Specifically for SNe Ia, SNID can accurately classify them when rlap > 15 without contamination from other types, such as Ibc, II, SLSN, and other objects that are not SNe (Purity > 98%). For other types, determining their classification is often uncertain. We conclude that it is difficult to obtain an accurate classification from these tools alone. This results in additional human visual inspection effort being required in order to confirm the classification. To reduce this human visual inspection and to support the classification process for future large-scale surveys, this work provides supporting information, such as the accuracy of each tool as a function of its metric.
format Preprint
id arxiv_https___arxiv_org_abs_2410_10963
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle How accurate are transient spectral classification tools? -- A study using 4,646 SEDMachine spectra
Kim, Young-Lo
Hook, Isobel
Milligan, Andrew
Galbany, Lluís
Sollerman, Jesper
Burgaz, Umut
Dimitriadis, Georgios
Fremling, Christoffer
Johansson, Joel
Müller-Bravo, Tomás E.
Neill, James D.
Nordin, Jakob
Nugent, Peter
Qi, Yu-Jing
Rosnet, Philippe
Sharma, Yashvi
Instrumentation and Methods for Astrophysics
Cosmology and Nongalactic Astrophysics
Solar and Stellar Astrophysics
Accurate classification of transients obtained from spectroscopic data are important to understand their nature and discover new classes of astronomical objects. For supernovae (SNe), SNID, NGSF (a Python version of SuperFit), and DASH are widely used in the community. Each tool provides its own metric to help determine classification, such as rlap of SNID, chi2/dof of NGSF, and Probability of DASH. However, we do not know how accurate these tools are, and they have not been tested with a large homogeneous dataset. Thus, in this work, we study the accuracy of these spectral classification tools using 4,646 SEDMachine spectra, which have accurate classifications obtained from the Zwicky Transient Facility Bright Transient Survey (BTS). Comparing our classifications with those from BTS, we have tested the classification accuracy in various ways. We find that NGSF has the best performance (overall Accuracy 87.6% when samples are split into SNe Ia and Non-Ia types), while SNID and DASH have similar performance with overall Accuracy of 79.3% and 76.2%, respectively. Specifically for SNe Ia, SNID can accurately classify them when rlap > 15 without contamination from other types, such as Ibc, II, SLSN, and other objects that are not SNe (Purity > 98%). For other types, determining their classification is often uncertain. We conclude that it is difficult to obtain an accurate classification from these tools alone. This results in additional human visual inspection effort being required in order to confirm the classification. To reduce this human visual inspection and to support the classification process for future large-scale surveys, this work provides supporting information, such as the accuracy of each tool as a function of its metric.
title How accurate are transient spectral classification tools? -- A study using 4,646 SEDMachine spectra
topic Instrumentation and Methods for Astrophysics
Cosmology and Nongalactic Astrophysics
Solar and Stellar Astrophysics
url https://arxiv.org/abs/2410.10963