实时数字波束形成扫描sar结构中TR模块的数字校准

J. Hoffman, D. Perkovic, S. Shaffer, L. Veilleux, E. Peral
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引用次数: 8

摘要

实时数字波束形成,结合轻型大孔径反射器,实现了一种新的架构,这是拟议的DESDynI[冰的变形、生态系统结构和动力学]SAR[合成孔径雷达]仪器(或DSI)的基础。这种新的仪器概念需要新的方法来校准多个同步通道。当前最先进的电子操纵阵列的校准通常包括飞行前TR(发射/接收)模块的温度特性,以及基于测量温度的飞行校正。这种方法忽略了元件老化和任何与温度无关的漂移的影响。我们正在开发新的数字波束形成阵列的数字校准,这有助于减少开发时间,风险和成本。精确校准的TR模块通过闭环数字校准精确跟踪模块特性,从而实现实时波束形成架构,无论温度如何都可以跟踪系统变化。这项工作的好处是,它将实现一种新的轻型雷达架构,带有机载数字波束形成。这为固体地球和生物质遥感提供了比传统SAR架构更大的覆盖范围,同时减少了任务质量和成本。
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Digital calibration of TR modules for real-time digital beamforming SweepSAR architectures
Real-time digital beamforming, combined with lightweight, large aperture reflectors, enable a new architecture, which is the baseline for the proposed DESDynI [Deformation, Ecosystem Structure, and Dynamics of Ice] SAR [Synthetic Aperture Radar] Instrument (or DSI). This new instrument concept requires new methods for calibrating multiple simultaneous channels. The calibration of current state-of-the-art Electronically Steered Arrays typically involves pre-flight TR (Transmit/Receive) module characterization over temperature, and in-flight correction based on measured temperatures. This method ignores the effects of element aging and any drifts unrelated to temperature. We are developing new digital calibration of digital beamforming arrays, which helps to reduce development time, risk and cost. Precision calibrated TR modules enable real-time beamforming architectures by accurately tracking modules' characteristics through closed-loop digital calibration, which tracks systematic changes regardless of temperature. The benefit of this effort is that it would enable a new, lightweight radar architecture, with on-board digital beamforming. This provides significantly larger swath coverage than conventional SAR architectures for solid earth and biomass remote sensing, while reducing mission mass and cost.
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