基于空间的 20 兆赫以下天空同步加速器频谱绝对通量测量的仪器误差预算

arXiv - PHYS - Instrumentation and Methods for Astrophysics Pub Date : 2024-09-09 DOI:arxiv-2409.06510

Julie Rolla, Andrew Romero-Wolf, Joseph Lazio

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引用次数: 0

摘要

这项工作描述了在电离层截止频率（<20 MHz）以下对天空同步辐射光谱绝对通量进行天基测量的仪器误差预算。我们将重点放在利用小型卫星上的电短偶极子的结构上。误差预算综合了偶极子尺寸、等离子噪声、杂散电容和前端放大器输入阻抗的贡献。我们使用蒙特卡罗误差传播模型和分析方法来处理误差。该误差预算可应用于各种实验，并最终用于提高天基电致短偶极子仪器的传感能力。更详细地探讨了个别不确定性成分，特别是游离电容的影响。

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An Instrument Error Budget for Space-Based Absolute Flux Measurements of the Sky Synchrotron Spectrum Below 20 MHz

This work describes the instrumental error budget for space-based measurements of the absolute flux of the sky synchrotron spectrum at frequencies below the ionospheric cutoff (<20 MHz). We focus on an architecture using electrically short dipoles onboard a small satellite. The error budget combines the contributions of the dipole dimensions, plasma noise, stray capacitance, and front-end amplifier input impedance. We treat the errors using both a Monte Carlo error propagation model and an analytical method. This error budget can be applied to a variety of experiments and used to ultimately improve the sensing capabilities of space-based electrically short dipole instruments. The impact of individual uncertainty components, particularly stray capacitance, is explored in more detail.

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arXiv - PHYS - Instrumentation and Methods for Astrophysics

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