Spectrally simplified approach for leveraging legacy geostationary
				oceanic observations

Houskeeper, Henry F.; Hooker, Stanford B.; Cavanaugh, Kyle C.

doi:10.1364/ao.465491

Cited by 3 publications

(2 citation statements)

References 39 publications

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“…The data underlying this article are available in Dryad at ( 59 ): Houskeeper, Henry; Hooker, Stanford (2023). Extending aquatic spectral information with the first radiometric IR-B field observations [Dataset].…”

Section: Data Availabilitymentioning

confidence: 99%

“…exploiting the UV and IR domains, improves the robustness of EOS remote sensing ( 10 ). End-member analysis (EMA)—which leverages information from the shortest and longest available wavebands—captures a greater dynamic range of environmental variability ( 6 , 13 ) and mitigates deleterious nonlinearities in VIS bio-optical relationships ( 9 ), thereby enabling globally consistent aquatic optical inversion algorithms ( 8 , 10 , 11 ). Despite recent spectral range expansions beyond the VIS domain, fundamental characteristics and potential radiometric applications of the aquatic light field remain incomplete and unexploited for much of the applicable electromagnetic spectrum.…”

Section: Introductionmentioning

confidence: 99%

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Extending aquatic spectral information with the first radiometric IR-B field observations

Houskeeper,

Hooker

2023

PNAS Nexus

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Planetary radiometric observations enable remote sensing of biogeochemical parameters to describe spatiotemporal variability in aquatic ecosystems. For approximately the last half century, the science of aquatic radiometry has established a knowledge base using primarily, but not exclusively, visible wavelengths. Scientific subdisciplines supporting aquatic radiometry have evolved hardware, software, and procedures to maximize competency for exploiting visible wavelength information. This perspective culminates with the science requirement that visible spectral resolution must be continually increased to extract more information. Other sources of information, meanwhile, remain underexploited, particularly information from nonvisible wavelengths. Herein, absolute radiometry is used to evaluate spectral limits for deriving and exploiting aquatic data products, specifically the normalized water-leaving radiance, Γ(λ), and its derivative products. Radiometric observations presented herein are quality assured for individual wavebands, and spectral verification is conducted by analyzing celestial radiometric results, comparing agreement of above- and in-water observations at applicable wavelengths, and evaluating consistency with bio-optical models and optical theory. The results presented include the first absolute radiometric field observations of Γ(λ) within the IR-B spectral domain (i.e. spanning 1400–3000 nm), which indicate that IR-B signals confer greater and more variable flux than formerly ascribed. Black-pixel processing, a routine correction in satellite and in situ aquatic radiometry wherein a spectrum is offset corrected relative to a nonvisible waveband (often IR-B or a shorter legacy waveband) set to a null value, is shown to degrade aquatic spectra and derived biogeochemical parameters.

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Section: Data Availabilitymentioning

confidence: 99%