We present improved photometric supernovae classification using deep recurrent neural networks. The main improvements over previous work are (i) the introduction of a time gate in the recurrent cell that uses the observational time as an input; (ii) greatly increased data augmentation including time translation, addition of Gaussian noise and early truncation of the lightcurve. For post Supernovae Photometric Classification Challenge (SPCC) data, using a training fraction of 5.2% (1103 supernovae) of a representational dataset, we obtain a type Ia vs. non type Ia classification accuracy of 93.2±0.1%, a Receiver Operating Characteristic curve AUC of 0.980±0.002 and a SPCC figure-of-merit of F1=0.57±0.01. Using a representational dataset of 50% (10660 supernovae), we obtain a classification accuracy of 96.6±0.1%, an AUC of 0.995±0.001 and F1=0.76±0.01. We found the non-representational training set of the SPCC resulted in a large degradation in performance due to a lack of faint supernovae, but this can be migrated by the introduction of only a small number (∼100) of faint training samples. We also outline ways in which this could be achieved using unsupervised domain adaptation.
@article{arxiv.1810.06441,
title = {Improved Photometric Classification of Supernovae using Deep Learning},
author = {Adam Moss},
journal= {arXiv preprint arXiv:1810.06441},
year = {2018}
}