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Sky-Scanning Sun-Tracking Airborne Radiometer (3STAR): Instrument Design, Flight Testing, and Tracking Performance The Sky-Scanning, Sun-Tracking Airborne Radiometer (3STAR) adapts commercial radiometer technology developed for the ocean color research community to airborne measurement of spectrally resolved solar irradiance and sky radiance. These atmospheric observations are used to derive aerosol optical depth (AOD), supporting localized AOD inputs for atmospheric correction of satellite and airborne data over terrestrial and aquatic (including optically dark) targets. The ability to regionally “tune” atmospheric correction schemes with relevant spatial AOD supports constraining atmospheric correction of remote sensing reflectance. Very wide dynamic range has been achieved for multi-channel band-pass-filter-radiometers originally designed for deployment into the water column. By actively tracking and directly pointing to the Sun, the light attenuation by aerosol particles in the atmospheric column can be quantified. These measurements improve knowledge of atmospheric constituents and the atmospheric corrections required to improve remote sensing capabilities for interpreting reflectance measurements from the Earth surface.

3STAR incorporates a custom Sun-tracking/sky-scanning pointing head, a Sun-tracking camera, and a commercially available, cylindrical, 19-channel radiometer tube assembly. An accurate and responsive mount and tracking system has been developed and certified to NASA and Naval Air Systems Command (NAVAIR) airworthiness standards for deployment into the aircraft slipstream. Ground and flight testing indicate typical tracking errors of less than 0.1 degrees, well within the field of view of the radiometer as required to minimize measurement uncertainty from alignment error. Preliminary AOD measurements compare to within 0.013 with 15 measurements from an Aerosol Robotic Network (AERONET) Cimel instrument at 500 nm wavelength and low solar angle.
Document ID
20210014303
Acquisition Source
Ames Research Center
Document Type
Technical Memorandum (TM)
Authors
Stephen E Dunagan
(Ames Research Center Mountain View, California, United States)
Liane Guild ORCID
(Ames Research Center Mountain View, California, United States)
James Eilers
(Ames Research Center Mountain View, California, United States)
Lauren Fahey
(Ames Research Center Mountain View, California, United States)
Yohei Shinozuka
(Universities Space Research Association Columbia, Maryland, United States)
Samuel Leblanc ORCID
(Bay Area Environmental Research Institute Petaluma, California, United States)
Conrad Esch
(Bay Area Environmental Research Institute Petaluma, California, United States)
Jordan Liss
(Bay Area Environmental Research Institute Petaluma, California, United States)
Scott Venancio
(Bay Area Environmental Research Institute Petaluma, California, United States)
Connor Flynn ORCID
(University of Oklahoma Norman, Oklahoma, United States)
Date Acquired
April 22, 2021
Publication Date
April 1, 2021
Subject Category
Earth Resources And Remote Sensing
Funding Number(s)
PROJECT: NNH16ZDA001N-AITT A.26
PROJECT: 2016 NASA-ARC SIF
PROJECT: ESD HQ2O
PROJECT: NNH12ZDA001N-WATER A.32
PROJECT: OCE HOPE 2010
Distribution Limits
Public
Copyright
Work of the US Gov. Public Use Permitted.
Technical Review
Single Expert
Keywords
Atmosphere
Climate
Pollution
Radiometry
Technology
Aerosol
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