Upgrades of the ESPERTA forecast tool for Solar Proton Events

Journal of Space Weather and Space Climate Pub Date : 2024-03-15 DOI:10.1051/swsc/2024007

M. Laurenza, M. Stumpo, Pietro Zucca, Mattia Mancini, S. Benella, L. Clark, Tommaso Alberti, Maria Federica Marcucci

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Abstract

The Empirical model for Solar Proton Events Real Time Alert (ESPERTA) exploits three solar parameters (flare longitude, soft X-ray fluence, and radio fluence) to provide a timely prediction for the occurrence of solar proton events (SPEs, i.e., when the $>$10MeV proton flux is $\geq$10 pfu) after the emission of a $\geq$ M2 flare. In addition, it makes a prediction for the more geoeffective SPEs for which the $>$10 MeV proton flux is $\geq$ 100 pfu. In this paper, we study two different ways to upgrade the ESPERTA model and implement it in real time: 1) by using ground based observations from the LOFAR stations; 2) by applying a novel machine learning algorithm to flare-based parameters to provide early warnings of SPE occurrence together with a fine-tuned radiation storm level. As a last step, we perform a preliminary study using a neural network to forecast the proton flux profile to complement the ESPERTA tool. We evaluate the models over flare and SPE data the last two solar cycles and discuss the performance and the limits and advantages of the three methods.

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ESPERTA太阳质子事件预报工具的升级

太阳质子事件实时警报经验模型（ESPERTA）利用三个太阳参数（耀斑经度、软X射线通量和射电通量），在发射$\geq$ M2耀斑后及时预测太阳质子事件（SPEs，即当$>$10MeV质子通量为$\geq$10 pfu时）的发生。此外，它还对地球效率更高的SPE进行了预测，即当$>$10MeV质子通量为$\geq$100 pfu时。在本文中，我们研究了两种不同的方法来升级ESPERTA模型并将其实时应用：1）利用LOFAR台站的地面观测数据；2）对基于耀斑的参数应用一种新颖的机器学习算法，以提供SPE发生的早期预警以及微调的辐射风暴水平。作为最后一步，我们利用神经网络对质子通量剖面进行了初步研究，以补充ESPERTA工具。我们对过去两个太阳周期的耀斑和SPE数据模型进行了评估，并讨论了这三种方法的性能、局限性和优势。

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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Journal of Space Weather and Space Climate

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