ARCSTONE: calibration of lunar spectral reflectance from space. Prototype instrument concept, analysis, and results

IF 1.4 4区地球科学 Q4 ENVIRONMENTAL SCIENCES

Journal of Applied Remote Sensing Pub Date : 2023-11-01 DOI:10.1117/1.jrs.17.044508

Hans Courrier, Rand Swanson, Constantine Lukashin, Christine Buleri, John Carvo, Michael Cooney, Warren Davis, Alexander Halterman, Alan Hoskins, Trevor Jackson, Mike Kehoe, Greg Kopp, Thuan Nguyen, Noah Ryan, Carlos Roithmayr, Paul Smith, Mike Stebbins, Thomas Stone, Cindy Young

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引用次数: 0

Abstract

The ARCSTONE project objective is to acquire accurate measurements of the spectral lunar reflectance from space, allowing the Moon to be used as a high-accuracy SI-traceable calibration reference by spaceborne sensors in low-Earth and geostationary orbits. The required spectral range is 350 to 2300 nm with 4-nm sampling. The ARCSTONE approach is to measure solar and lunar spectral irradiances with a single set of optics and determine spectrally resolved lunar reflectances via a direct ratioing method, eliminating long-term optical degradation effects. Lunar-irradiance values, derived from these direct reflectance measurements, are enabled by independently measured SI-traceable spectral solar irradiances, essentially using the Sun as an on-orbit calibration reference. In an initial attempt to demonstrate this approach, a prototype ultraviolet-visible-near infrared (348 to 910 nm) instrument was designed, fully assembled, characterized, and field tested. Our results demonstrate that this prototype ARCSTONE instrument provides a dynamic range larger than 106, which is necessary to directly measure both the solar and lunar signals, and suggest uncertainties better than 0.5% (k = 1) in measuring lunar spectra can be achieved under proper operational scenarios. We present the design, characterization, and proof-of-concept field-test of the ARCSTONE instrument prototype.

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ARCSTONE:从太空校准月球光谱反射率。原型仪器的概念、分析和结果

ARCSTONE项目的目标是从空间获得月球光谱反射率的精确测量值，使月球能够作为低地球和地球静止轨道上的星载传感器的高精度si可追踪校准参考。所需的光谱范围为350至2300 nm，采样为4 nm。ARCSTONE方法是用一套光学器件测量太阳和月球的光谱辐照度，并通过直接比例法确定光谱分辨的月球反射率，消除长期光学退化效应。从这些直接反射率测量中得出的月球辐照度值是通过独立测量的si可追溯光谱太阳辐照度来实现的，本质上是使用太阳作为在轨校准参考。为了演示这种方法，我们设计了一个原型紫外-可见-近红外(348至910 nm)仪器，并进行了完全组装、表征和现场测试。结果表明，原型ARCSTONE仪器提供了大于106的动态范围，这是直接测量太阳和月球信号所必需的，并且表明在适当的操作场景下，测量月球光谱的不确定性可以达到小于0.5% (k = 1)。我们介绍了ARCSTONE仪器原型的设计、表征和概念验证现场测试。

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来源期刊

Journal of Applied Remote Sensing 环境科学-成像科学与照相技术

CiteScore

3.40

自引率

11.80%

发文量

194

审稿时长

3 months

期刊介绍： The Journal of Applied Remote Sensing is a peer-reviewed journal that optimizes the communication of concepts, information, and progress among the remote sensing community.