2021
DOI: 10.1051/0004-6361/202037709
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Active anomaly detection for time-domain discoveries

Abstract: Aims. We present the first piece of evidence that adaptive learning techniques can boost the discovery of unusual objects within astronomical light curve data sets. Methods. Our method follows an active learning strategy where the learning algorithm chooses objects that can potentially improve the learner if additional information about them is provided. This new information is subsequently used to update the machine learning model, allowing its accuracy to evolve with each new piece of information. For the ca… Show more

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Cited by 32 publications
(16 citation statements)
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“…In practice, the detection of novel transients should involve a feedback loop where resources are dedicated to followup candidates, and where these are then added back into the training set. This form of "active learning" is discussed in detail in Ishida et al (2019) and an application to isolation forests for anomaly detection is discussed in Ishida et al (2021). The ParSNIP model is ideally suited to being used with these techniques.…”
Section: Detecting Novel Transientsmentioning
confidence: 99%
“…In practice, the detection of novel transients should involve a feedback loop where resources are dedicated to followup candidates, and where these are then added back into the training set. This form of "active learning" is discussed in detail in Ishida et al (2019) and an application to isolation forests for anomaly detection is discussed in Ishida et al (2021). The ParSNIP model is ideally suited to being used with these techniques.…”
Section: Detecting Novel Transientsmentioning
confidence: 99%
“…Active learning has already shown to be successful in astronomy, for example, in estimating parameters of stellar population synthesis models by Solorio et al (2005) or for the classification of light curves of variable stars by Richards et al (2012). Gupta et al (2016) used active learning to learn a model for photometric data classification from spectroscopic data (the work was extended by Vilalta et al (2019)), and recently, active learning was used to minimise the number of required spectroscopically confirmed labels in preparing training sets for the photometric classification of supernova light curves by Ishida et al (2019a) and for active anomaly detection in light curves of supernovae by Ishida et al (2019b). Moreover, active deep learning has been successfully tested in remote sensing by Liu et al (2017), with further examples reviewed in Yang et al (2018).…”
Section: Active Learningmentioning
confidence: 99%
“…The SNAD 2 team has been continuously working in the development of anomaly detection algorithms which are able to prove their efficiency in real data while incorporating domain knowledge in the machine learning model -thus tailoring it according to the scientific interest of the expert (e.g., Pruzhinskaya et al, 2019;Aleo et al, 2020;Malanchev et al, 2021;Ishida et al, 2021). In this work, we present a hybrid approach for mining transients in large astronomical datasets, specifically ZTF DR4; moreover, our methodology can also be applied to the nightly ZTF alert-stream via timedomain brokers like ANTARES (Matheson et al, 2021) and FINK (Möller et al, 2021).…”
Section: Introductionmentioning
confidence: 99%