Machine learning for transient recognition in difference imaging with minimum sampling effort

Y. L. Mong; K. Ackley; D. K. Galloway; T. Killestein; J. Lyman; D. Steeghs; V. Dhillon; P. T. O'Brien; G. Ramsay; S. Poshyachinda; R. Kotak; L. Nuttall; E. Pallé; D. Pollacco; E. Thrane; M. J. Dyer; K. Ulaczyk; R. Cutter; J. McCormac; P. Chote; A. J. Levan; T. Marsh; E. Stanway; B. Gompertz; K. Wiersema; A. Chrimes; A. Obradovic; J. Mullaney; E. Daw; S. Littlefair; J. Maund; L. Makrygianni; U. Burhanudin; R. L.C. Starling; R. A.J. Eyles-Ferris; S. Tooke; C. Duffy; S. Aukkaravittayapun; U. Sawangwit; S. Awiphan; D. Mkrtichian; P. Irawati; S. Mattila; T. Heikkilä; R. Breton; M. Kennedy; D. Mata Sánchez; E. Rol

doi:10.1093/MNRAS/STAA3096

Machine learning for transient recognition in difference imaging with minimum sampling effort

Y. L. Mong
, K. Ackley
, D. K. Galloway
, T. Killestein
, J. Lyman
, D. Steeghs
, V. Dhillon
, P. T. O'Brien
, G. Ramsay
, S. Poshyachinda
, R. Kotak
, L. Nuttall
, E. Pallé
, D. Pollacco
, E. Thrane
, M. J. Dyer
, K. Ulaczyk
, R. Cutter
, J. McCormac
, P. Chote

A. J. Levan, T. Marsh, E. Stanway, B. Gompertz, K. Wiersema, A. Chrimes, A. Obradovic, J. Mullaney, E. Daw, S. Littlefair, J. Maund, L. Makrygianni, U. Burhanudin, R. L.C. Starling, R. A.J. Eyles-Ferris, S. Tooke, C. Duffy, S. Aukkaravittayapun, U. Sawangwit, S. Awiphan, D. Mkrtichian, P. Irawati, S. Mattila, T. Heikkilä, R. Breton, M. Kennedy, D. Mata Sánchez, E. Rol

Monash University
ARC Centre of Excellence for Gravitational Wave Discovery
University of Warwick
University of Sheffield
University of Leicester
Armagh Observatory
National Astronomical Research Institute of Thailand
University of Turku
University of Portsmouth
Instituto de Astrofísica de Canarias
University of Manchester

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

Abstract

The amount of observational data produced by time-domain astronomy is exponentially increasing. Human inspection alone is not an effective way to identify genuine transients from the data. An automatic real-bogus classifier is needed and machine learning techniques are commonly used to achieve this goal. Building a training set with a sufficiently large number of verified transients is challenging, due to the requirement of human verification. We present an approach for creating a training set by using all detections in the science images to be the sample of real detections and all detections in the difference images, which are generated by the process of difference imaging to detect transients, to be the samples of bogus detections. This strategy effectively minimizes the labour involved in the data labelling for supervised machine learning methods. We demonstrate the utility of the training set by using it to train several classifiers utilizing as the feature representation the normalized pixel values in 21 × 21 pixel stamps centred at the detection position, observed with the Gravitational-wave Optical Transient Observer (GOTO) prototype. The real-bogus classifier trained with this strategy can provide up to 95 per cent prediction accuracy on the real detections at a false alarm rate of 1 per cent.

Original language	English
Pages (from-to)	6009-6017
Number of pages	9
Journal	Monthly Notices of the Royal Astronomical Society
Volume	499
Issue number	4
DOIs	https://doi.org/10.1093/MNRAS/STAA3096
Publication status	Published - 2020
Externally published	Yes

Keywords

Methods: data analysis
Methods: statistical
Techniques: image processing.

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10.1093/MNRAS/STAA3096

Cite this

Mong, Y. L., Ackley, K., Galloway, D. K., Killestein, T., Lyman, J., Steeghs, D., Dhillon, V., O'Brien, P. T., Ramsay, G., Poshyachinda, S., Kotak, R., Nuttall, L., Pallé, E., Pollacco, D., Thrane, E., Dyer, M. J., Ulaczyk, K., Cutter, R., McCormac, J., ... Rol, E. (2020). Machine learning for transient recognition in difference imaging with minimum sampling effort. Monthly Notices of the Royal Astronomical Society, 499(4), 6009-6017. https://doi.org/10.1093/MNRAS/STAA3096

@article{81e6ed9cb1f14194a91faa234348f050,

title = "Machine learning for transient recognition in difference imaging with minimum sampling effort",

abstract = "The amount of observational data produced by time-domain astronomy is exponentially increasing. Human inspection alone is not an effective way to identify genuine transients from the data. An automatic real-bogus classifier is needed and machine learning techniques are commonly used to achieve this goal. Building a training set with a sufficiently large number of verified transients is challenging, due to the requirement of human verification. We present an approach for creating a training set by using all detections in the science images to be the sample of real detections and all detections in the difference images, which are generated by the process of difference imaging to detect transients, to be the samples of bogus detections. This strategy effectively minimizes the labour involved in the data labelling for supervised machine learning methods. We demonstrate the utility of the training set by using it to train several classifiers utilizing as the feature representation the normalized pixel values in 21 × 21 pixel stamps centred at the detection position, observed with the Gravitational-wave Optical Transient Observer (GOTO) prototype. The real-bogus classifier trained with this strategy can provide up to 95 per cent prediction accuracy on the real detections at a false alarm rate of 1 per cent.",

keywords = "Methods: data analysis, Methods: statistical, Techniques: image processing.",

author = "Mong, \{Y. L.\} and K. Ackley and Galloway, \{D. K.\} and T. Killestein and J. Lyman and D. Steeghs and V. Dhillon and O'Brien, \{P. T.\} and G. Ramsay and S. Poshyachinda and R. Kotak and L. Nuttall and E. Pall{\'e} and D. Pollacco and E. Thrane and Dyer, \{M. J.\} and K. Ulaczyk and R. Cutter and J. McCormac and P. Chote and Levan, \{A. J.\} and T. Marsh and E. Stanway and B. Gompertz and K. Wiersema and A. Chrimes and A. Obradovic and J. Mullaney and E. Daw and S. Littlefair and J. Maund and L. Makrygianni and U. Burhanudin and Starling, \{R. L.C.\} and Eyles-Ferris, \{R. A.J.\} and S. Tooke and C. Duffy and S. Aukkaravittayapun and U. Sawangwit and S. Awiphan and D. Mkrtichian and P. Irawati and S. Mattila and T. Heikkil{\"a} and R. Breton and M. Kennedy and S{\'a}nchez, \{D. Mata\} and E. Rol",

note = "Publisher Copyright: {\textcopyright} 2020 The Author(s).",

year = "2020",

doi = "10.1093/MNRAS/STAA3096",

language = "English",

volume = "499",

pages = "6009--6017",

journal = "Monthly Notices of the Royal Astronomical Society",

issn = "0035-8711",

publisher = "Oxford University Press",

number = "4",

}

Mong, YL, Ackley, K, Galloway, DK, Killestein, T, Lyman, J, Steeghs, D, Dhillon, V, O'Brien, PT, Ramsay, G, Poshyachinda, S, Kotak, R, Nuttall, L, Pallé, E, Pollacco, D, Thrane, E, Dyer, MJ, Ulaczyk, K, Cutter, R, McCormac, J, Chote, P, Levan, AJ, Marsh, T, Stanway, E, Gompertz, B, Wiersema, K, Chrimes, A, Obradovic, A, Mullaney, J, Daw, E, Littlefair, S, Maund, J, Makrygianni, L, Burhanudin, U, Starling, RLC, Eyles-Ferris, RAJ, Tooke, S, Duffy, C, Aukkaravittayapun, S, Sawangwit, U, Awiphan, S, Mkrtichian, D, Irawati, P, Mattila, S, Heikkilä, T, Breton, R, Kennedy, M, Sánchez, DM & Rol, E 2020, 'Machine learning for transient recognition in difference imaging with minimum sampling effort', Monthly Notices of the Royal Astronomical Society, vol. 499, no. 4, pp. 6009-6017. https://doi.org/10.1093/MNRAS/STAA3096

TY - JOUR

T1 - Machine learning for transient recognition in difference imaging with minimum sampling effort

AU - Mong, Y. L.

AU - Ackley, K.

AU - Galloway, D. K.

AU - Killestein, T.

AU - Lyman, J.

AU - Steeghs, D.

AU - Dhillon, V.

AU - O'Brien, P. T.

AU - Ramsay, G.

AU - Poshyachinda, S.

AU - Kotak, R.

AU - Nuttall, L.

AU - Pallé, E.

AU - Pollacco, D.

AU - Thrane, E.

AU - Dyer, M. J.

AU - Ulaczyk, K.

AU - Cutter, R.

AU - McCormac, J.

AU - Chote, P.

AU - Levan, A. J.

AU - Marsh, T.

AU - Stanway, E.

AU - Gompertz, B.

AU - Wiersema, K.

AU - Chrimes, A.

AU - Obradovic, A.

AU - Mullaney, J.

AU - Daw, E.

AU - Littlefair, S.

AU - Maund, J.

AU - Makrygianni, L.

AU - Burhanudin, U.

AU - Starling, R. L.C.

AU - Eyles-Ferris, R. A.J.

AU - Tooke, S.

AU - Duffy, C.

AU - Aukkaravittayapun, S.

AU - Sawangwit, U.

AU - Awiphan, S.

AU - Mkrtichian, D.

AU - Irawati, P.

AU - Mattila, S.

AU - Heikkilä, T.

AU - Breton, R.

AU - Kennedy, M.

AU - Sánchez, D. Mata

AU - Rol, E.

PY - 2020

Y1 - 2020

N2 - The amount of observational data produced by time-domain astronomy is exponentially increasing. Human inspection alone is not an effective way to identify genuine transients from the data. An automatic real-bogus classifier is needed and machine learning techniques are commonly used to achieve this goal. Building a training set with a sufficiently large number of verified transients is challenging, due to the requirement of human verification. We present an approach for creating a training set by using all detections in the science images to be the sample of real detections and all detections in the difference images, which are generated by the process of difference imaging to detect transients, to be the samples of bogus detections. This strategy effectively minimizes the labour involved in the data labelling for supervised machine learning methods. We demonstrate the utility of the training set by using it to train several classifiers utilizing as the feature representation the normalized pixel values in 21 × 21 pixel stamps centred at the detection position, observed with the Gravitational-wave Optical Transient Observer (GOTO) prototype. The real-bogus classifier trained with this strategy can provide up to 95 per cent prediction accuracy on the real detections at a false alarm rate of 1 per cent.

AB - The amount of observational data produced by time-domain astronomy is exponentially increasing. Human inspection alone is not an effective way to identify genuine transients from the data. An automatic real-bogus classifier is needed and machine learning techniques are commonly used to achieve this goal. Building a training set with a sufficiently large number of verified transients is challenging, due to the requirement of human verification. We present an approach for creating a training set by using all detections in the science images to be the sample of real detections and all detections in the difference images, which are generated by the process of difference imaging to detect transients, to be the samples of bogus detections. This strategy effectively minimizes the labour involved in the data labelling for supervised machine learning methods. We demonstrate the utility of the training set by using it to train several classifiers utilizing as the feature representation the normalized pixel values in 21 × 21 pixel stamps centred at the detection position, observed with the Gravitational-wave Optical Transient Observer (GOTO) prototype. The real-bogus classifier trained with this strategy can provide up to 95 per cent prediction accuracy on the real detections at a false alarm rate of 1 per cent.

KW - Methods: data analysis

KW - Methods: statistical

KW - Techniques: image processing.

UR - https://www.scopus.com/pages/publications/85099775364

U2 - 10.1093/MNRAS/STAA3096

DO - 10.1093/MNRAS/STAA3096

M3 - Article

AN - SCOPUS:85099775364

SN - 0035-8711

VL - 499

SP - 6009

EP - 6017

JO - Monthly Notices of the Royal Astronomical Society

JF - Monthly Notices of the Royal Astronomical Society

IS - 4

ER -

Machine learning for transient recognition in difference imaging with minimum sampling effort

Abstract

Keywords

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