# Machine Learning for the Zwicky Transient Facility

**Authors:** Ashish Mahabal, Umaa Rebbapragada, Richard Walters, Frank J. Masci,, Nadejda Blagorodnova, Jan van Roestel, Quan-Zhi Ye, Rahul Biswas, Kevin, Burdge, Chan-Kao Chang, Dmitry A. Duev, V. Zach Golkhou, Adam A. Miller,, Jakob Nordin, Charlotte Ward, Scott Adams, Eric C. Bellm, Doug Branton, Brian, Bue, Chris Cannella, Andrew Connolly, Richard Dekany, Ulrich Feindt, Tiara, Hung, Lucy Fortson, Sara Frederick, C. Fremling, Suvi Gezari, Matthew Graham,, Steven Groom, Mansi M. Kasliwal, Shrinivas Kulkarni, Thomas Kupfer, Hsing Wen, Lin, Chris Lintott, Ragnhild Lunnan, John Parejko, Thomas A. Prince, Reed, Riddle, Ben Rusholme, Nicholas Saunders, Nima Sedaghat, David L. Shupe, Leo, P. Singer, Maayane T. Soumagnac, Paula Szkody, Yutaro Tachibana, Kushal, Tirumala, Sjoert van Velzen, and Darryl Wright

arXiv: 1902.01936 · 2019-02-07

## TL;DR

This paper discusses machine learning techniques applied to the Zwicky Transient Facility data, focusing on classification, anomaly detection, and leveraging deep learning and domain adaptation to enhance transient object identification.

## Contribution

It introduces various ML implementations and plans for ZTF data, including deep learning, domain adaptation, and active learning strategies for transient classification.

## Key findings

- Effective separation of real and bogus candidates
- Successful classification of stars and galaxies
- Initial plans for deep learning and domain adaptation methods

## Abstract

The Zwicky Transient Facility is a large optical survey in multiple filters producing hundreds of thousands of transient alerts per night. We describe here various machine learning (ML) implementations and plans to make the maximal use of the large data set by taking advantage of the temporal nature of the data, and further combining it with other data sets. We start with the initial steps of separating bogus candidates from real ones, separating stars and galaxies, and go on to the classification of real objects into various classes. Besides the usual methods (e.g., based on features extracted from light curves) we also describe early plans for alternate methods including the use of domain adaptation, and deep learning. In a similar fashion we describe efforts to detect fast moving asteroids. We also describe the use of the Zooniverse platform for helping with classifications through the creation of training samples, and active learning. Finally we mention the synergistic aspects of ZTF and LSST from the ML perspective.

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Source: https://tomesphere.com/paper/1902.01936