全面鉴定海洋颜色辐射计

Viktor Vabson, I. Ansko, Kim Duong, R. Vendt, Joel Kuusk, Kevin G. Ruddick, Agnieszka Bialek, G. Tilstone, J. I. Gossn, Ewa Kwiatkowska
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引用次数: 0

摘要

为准确推导海洋/水色生物地球物理产品而验证和确认来自空间的漏水辐射测量值,是以在地面或水体上同时进行的高质量基准测量(FRM)为基础的。地球观测卫星委员会(CEOS)制定的 "基准参照测量原则 "建议,原地海洋颜色辐射计(OCR)应具有记录在案的 SI 可追溯校准历史,包括不确定性预算。此外,由于工作温度、光场角度变化(尤其是辐照度传感器)、测量的辐射强度和目标的光谱变化等因素的不同,仪器的校准和实地使用之间可能存在很大差异。这些因素中的每一个在实地部署时都可能与仪器的个别特性发生相互作用,如果要将扩大的不确定性控制在±10%(k = 2)范围内,则除了绝对辐射校准之外,还需要对仪器特性进行估计。FRM4SOC 第 2 阶段项目由欧洲委员会在哥白尼计划框架内资助,由欧洲气象卫星应用组织实施,该项目为这些工作做出了贡献,旨在开发一个具有 FRM 质量的辐射测量操作和持续网络。在 FRM4SOC-2 中,塔尔图大学塔尔图天文台(Tartu Observatory,TO)的科学家们对一组 37 个高光谱场辐射计进行了前所未有的校准和特性分析,这些辐射计代表了 OC 界最常用的 OCR 类别。所进行的校准和特征描述包括确定辐射响应度、长期稳定性、光谱刻度的准确性、非线性和积分时间的准确性、光谱杂散光、空气中辐照度传感器的角度响应、暗信号、热灵敏度、偏振灵敏度以及各 OCR 的信噪比。需要对不同仪器和测量模型获得的原地数据进行一致的偏差校正和扩展的不确定性分析程序,这正是本文的目的所在。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Complete characterization of ocean color radiometers
Verifying and validating waterleaving radiance measurements from space for an accurate derivation of Ocean/Water Colour biogeophysical products is based on concurrent high-quality fiducial reference measurements (FRM) carried out on the ground or water body. The FRM principles established by the Committee on Earth Observation Satellites (CEOS) recommend that in situ Ocean Colour radiometers (OCR) have a documented history of SI traceable calibrations including uncertainty budgets. Furthermore, there can be significant differences between calibration and use of the instruments in the field due to differences in operating temperature, angular variation of the light field (especially for irradiance sensors), the intensity of the measured radiation, and spectral variation of the target, among others. Each of these factors may interact with individual properties of the instrument when deployed in the field, and estimation of such uncertainties requires instrument characterization in addition to the absolute radiometric calibration if expanded uncertainties within ±10% (k = 2) are the aim. The FRM4SOC Phase 2 project - funded by the European Commission in the frame of the Copernicus Programme and implemented by EUMETSAT - contributes to these efforts, aiming at developing an operational and sustained network of radiometric measurements of FRM quality. Within FRM4SOC-2, scientists from the Tartu Observatory (TO) of the University of Tartu performed an unprecedented batch of calibrations and characterizations on a set of 37 hyperspectral field radiometers representative of the most used OCR classes within the OC community. The calibrations and characterizations performed include the determination of radiometric responsivity, long-term stability, the accuracy of the spectral scale, non-linearity and accuracy of integration times, spectral stray light, angular response of irradiance sensors in air, dark signal, thermal sensitivity, polarization sensitivity, and signal-to-noise ratio of individual OCRs. Consistent correction of biases and extended uncertainty analysis procedures of in situ data obtained from different instruments and measurement models need to be clearly defined, which is the objective of this paper.
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