High-Resolution Radiometer for Remote Sensing of Solar Flare Activity from Low Earth Orbit Satellites

Journal of Atmospheric Science Research Pub Date : 2019-01-04 DOI:10.30564/JASR.V1I1.420

L. Aluigi

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引用次数: 1

Abstract

Solar flares, intense bursts of radiation, can disrupt the atmosphere and potentially affect communication, navigation and electrical systems. A newly developed miniaturised microwave radiometer used on a space-borne platform should offer astronomers unprecedented understanding of the largest explosive phenomena in our solar system. In this paper the activity and results of the EU funded research project FLARES are presented. Objective of FLARES has been the study, analysis and design of millimetre-wave (mm-wave) system-on-chip (SoC) radiometer for space-borne detection of solar flares. The proposed approach has contributed to reduce significantly the power consumption and weight with respect to the existing instruments for the observation and study of solar flares. In particular, the proposed SoC Dicke radiometer can achieve one order of magnitude improvement in terms of resolution, so allowing the detection of solar flares with relatively low intensity, i.e. about 100 times lower than those currently detected by the existing systems, owing to space-borne operations and the microchip-level miniaturization through silicon technology under space qualification.

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用于近地轨道卫星遥感太阳耀斑活动的高分辨率辐射计

太阳耀斑是一种强烈的辐射爆发，可以破坏大气，并可能影响通信、导航和电力系统。一种新开发的用于太空平台的微型微波辐射计将为天文学家提供对太阳系中最大爆炸现象的前所未有的了解。本文介绍了欧盟资助的研究项目FLARES的活动和成果。FLARES的目标是研究、分析和设计用于星载太阳耀斑探测的毫米波片上系统(SoC)辐射计。与现有的观测和研究太阳耀斑的仪器相比，所提出的方法有助于大大减少功率消耗和重量。特别是，所提出的SoC Dicke辐射计在分辨率上可以实现一个数量级的提高，因此可以以相对较低的强度探测太阳耀斑，即比现有系统低100倍左右，这得益于空间条件下的星载操作和通过硅技术实现的微芯片级小型化。

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 Atmospheric Science Research

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