Panopticon: a novel deep learning model to detect single transit events with no prior data filtering in PLATO light curves

arXiv - PHYS - Instrumentation and Methods for Astrophysics Pub Date : 2024-09-05 DOI:arxiv-2409.03466

H. G. Vivien, M. Deleuil, N. Jannsen, J. De Ridder, D. Seynaeve, M. -A. Carpine, Y. Zerah

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Abstract

To prepare for the analyses of the future PLATO light curves, we develop a deep learning model, Panopticon, to detect transits in high precision photometric light curves. Since PLATO's main objective is the detection of temperate Earth-size planets around solar-type stars, the code is designed to detect individual transit events. The filtering step, required by conventional detection methods, can affect the transit, which could be an issue for long and shallow transits. To protect transit shape and depth, the code is also designed to work on unfiltered light curves. We trained the model on a set of simulated PLATO light curves in which we injected, at pixel level, either planetary, eclipsing binary, or background eclipsing binary signals. We also include a variety of noises in our data, such as granulation, stellar spots or cosmic rays. The approach is able to recover 90% of our test population, including more than 25% of the Earth-analogs, even in the unfiltered light curves. The model also recovers the transits irrespective of the orbital period, and is able to retrieve transits on a unique event basis. These figures are obtained when accepting a false alarm rate of 1%. When keeping the false alarm rate low (<0.01%), it is still able to recover more than 85% of the transit signals. Any transit deeper than 180ppm is essentially guaranteed to be recovered. This method is able to recover transits on a unique event basis, and does so with a low false alarm rate. Thanks to light curves being one-dimensional, model training is fast, on the order of a few hours per model. This speed in training and inference, coupled to the recovery effectiveness and precision of the model make it an ideal tool to complement, or be used ahead of, classical approaches.

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Panopticon：一种新颖的深度学习模型，无需事先过滤 PLATO 光曲线中的数据，即可检测单次过境事件

为了准备对未来的 PLATO 光曲线进行分析，我们开发了一个深度学习模型 "Panopticon"，用于探测高精度光度计光曲线中的凌日现象。由于PLATO的主要目标是探测太阳型恒星周围的温带地球大小的行星，因此该代码旨在探测单个凌日事件。传统探测方法所需的滤波步骤可能会影响凌日，这对于较长和较浅的凌日来说可能是个问题。为了保护凌日的形状和深度，代码还被设计用于未过滤的光曲线。我们在一组模拟PLATO光曲线上训练了模型，在这些光曲线中，我们在像素级注入了行星信号、双星食变信号或背景双星食变信号。我们还在数据中加入了各种噪声，如颗粒、恒星斑点或宇宙射线。该方法能够恢复 90% 的测试星群，包括 25% 以上的地球模拟星，即使在未滤波的光曲线中也是如此。该模型还能恢复出与轨道周期无关的凌日，并能以唯一事件为基础恢复凌日。这些数据是在误报率为 1%的情况下得出的。当误报率保持在较低水平（<0.01%）时，它仍能恢复 85% 以上的凌日信号。任何深度超过 180ppm 的信号基本上都能保证被恢复。这种方法能够以唯一事件为基础恢复凌日信号，而且误报率很低。由于光变曲线是一维的，因此模型训练速度很快，每个模型只需几个小时。这种训练和推理的速度，加上模型的恢复效果和精确度，使它成为一种理想的工具，可以补充或先于传统方法使用。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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arXiv - PHYS - Instrumentation and Methods for Astrophysics

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