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Main Authors: Sharma, Yashvi, Mahabal, Ashish A., Sollerman, Jesper, Fremling, Christoffer, Kulkarni, S. R., Rehemtulla, Nabeel, Miller, Adam A., Aubert, Marie, Chen, Tracy X., Coughlin, Michael W., Graham, Matthew J., Hale, David, Kasliwal, Mansi M., Kim, Young-Lo, Neill, James D., Purdum, Josiah N., Rusholme, Ben, Singh, Avinash, Sravan, Niharika
Format: Preprint
Published: 2024
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Online Access:https://arxiv.org/abs/2412.08601
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author Sharma, Yashvi
Mahabal, Ashish A.
Sollerman, Jesper
Fremling, Christoffer
Kulkarni, S. R.
Rehemtulla, Nabeel
Miller, Adam A.
Aubert, Marie
Chen, Tracy X.
Coughlin, Michael W.
Graham, Matthew J.
Hale, David
Kasliwal, Mansi M.
Kim, Young-Lo
Neill, James D.
Purdum, Josiah N.
Rusholme, Ben
Singh, Avinash
Sravan, Niharika
author_facet Sharma, Yashvi
Mahabal, Ashish A.
Sollerman, Jesper
Fremling, Christoffer
Kulkarni, S. R.
Rehemtulla, Nabeel
Miller, Adam A.
Aubert, Marie
Chen, Tracy X.
Coughlin, Michael W.
Graham, Matthew J.
Hale, David
Kasliwal, Mansi M.
Kim, Young-Lo
Neill, James D.
Purdum, Josiah N.
Rusholme, Ben
Singh, Avinash
Sravan, Niharika
contents Supernovae (SNe) come in various flavors and are classified into different types based on emission and absorption lines in their spectra. SN candidates are now abundant with the advent of large systematic sky surveys like the Zwicky Transient Facility (ZTF), however, the identification bottleneck lies in their spectroscopic confirmation and classification. Fully robotic telescopes with dedicated spectrographs optimized for SN follow-up have eased the burden of data acquisition. However, the task of classifying the spectra still largely rests with the astronomers. Automating this classification step reduces human effort and can make the SN type available sooner to the public. For this purpose, we have developed a deep-learning based program for classifying core-collapse supernovae (CCSNe) with ultra-low resolution spectra from the SED-Machine spectrograph on the Palomar 60-inch telescope. The program consists of hierarchical classification task layers, with each layer composed of multiple binary classifiers running in parallel to produce a reliable classification. The binary classifiers utilize RNN and CNN architecture and are designed to take multiple inputs to supplement spectra with $g$- and $r$-band photometry from ZTF. On non-host-contaminated and good quality SEDM spectra ("gold" test set) of CCSNe, CCSNscore is ~94% accurate in distinguishing between hydrogen-rich (Type II) and hydrogen-poor (Type Ibc) CCSNe. With light curve input, CCSNscore classifies ~83% of the gold set with high confidence (score $\geq 0.8$ and score-error $<0.05$), with ~98% accuracy. Based on SNIascore's and CCSNscore's real-time performance on bright transients ($m_{pk}\leq18.5$) and our reporting criteria, we expect ~0.5% (~4) true SNe Ia to be misclassified as SNe Ibc and ~6% (~17) of true CCSNe to be misclassified between Type II and Type Ibc annually on the Transient Name Server.
format Preprint
id arxiv_https___arxiv_org_abs_2412_08601
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle CCSNscore: A multi-input deep learning tool for classification of core-collapse supernovae using SED-Machine spectra
Sharma, Yashvi
Mahabal, Ashish A.
Sollerman, Jesper
Fremling, Christoffer
Kulkarni, S. R.
Rehemtulla, Nabeel
Miller, Adam A.
Aubert, Marie
Chen, Tracy X.
Coughlin, Michael W.
Graham, Matthew J.
Hale, David
Kasliwal, Mansi M.
Kim, Young-Lo
Neill, James D.
Purdum, Josiah N.
Rusholme, Ben
Singh, Avinash
Sravan, Niharika
Instrumentation and Methods for Astrophysics
Supernovae (SNe) come in various flavors and are classified into different types based on emission and absorption lines in their spectra. SN candidates are now abundant with the advent of large systematic sky surveys like the Zwicky Transient Facility (ZTF), however, the identification bottleneck lies in their spectroscopic confirmation and classification. Fully robotic telescopes with dedicated spectrographs optimized for SN follow-up have eased the burden of data acquisition. However, the task of classifying the spectra still largely rests with the astronomers. Automating this classification step reduces human effort and can make the SN type available sooner to the public. For this purpose, we have developed a deep-learning based program for classifying core-collapse supernovae (CCSNe) with ultra-low resolution spectra from the SED-Machine spectrograph on the Palomar 60-inch telescope. The program consists of hierarchical classification task layers, with each layer composed of multiple binary classifiers running in parallel to produce a reliable classification. The binary classifiers utilize RNN and CNN architecture and are designed to take multiple inputs to supplement spectra with $g$- and $r$-band photometry from ZTF. On non-host-contaminated and good quality SEDM spectra ("gold" test set) of CCSNe, CCSNscore is ~94% accurate in distinguishing between hydrogen-rich (Type II) and hydrogen-poor (Type Ibc) CCSNe. With light curve input, CCSNscore classifies ~83% of the gold set with high confidence (score $\geq 0.8$ and score-error $<0.05$), with ~98% accuracy. Based on SNIascore's and CCSNscore's real-time performance on bright transients ($m_{pk}\leq18.5$) and our reporting criteria, we expect ~0.5% (~4) true SNe Ia to be misclassified as SNe Ibc and ~6% (~17) of true CCSNe to be misclassified between Type II and Type Ibc annually on the Transient Name Server.
title CCSNscore: A multi-input deep learning tool for classification of core-collapse supernovae using SED-Machine spectra
topic Instrumentation and Methods for Astrophysics
url https://arxiv.org/abs/2412.08601