Retrieval of water-leaving radiance and aerosol optical thickness over the oceans with SeaWiFS: a preliminary algorithm.

@article{Gordon1994RetrievalOW,
  title={Retrieval of water-leaving radiance and aerosol optical thickness over the oceans with SeaWiFS: a preliminary algorithm.},
  author={Howard R. Gordon and M. Wang},
  journal={Applied optics},
  year={1994},
  volume={33 3},
  pages={
          443-52
        }
}
The second generation of ocean-color-analyzing instruments requires more accurate atmospheric correction than does the Coastal Zone Color Scanner (CZCS), if one is to utilize fully their increased radiometric sensitivity. Unlike the CZCS, the new instruments possess bands in the near infrared (NIR) that are solely for aiding atmospheric correction. We show, using aerosol models, that certain assumptions regarding the spectral behavior of the aerosol reflectance employed in the standard CZCS… 
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References

SHOWING 1-10 OF 72 REFERENCES
Surface-roughness considerations for atmospheric correction of ocean color sensors. I: The Rayleigh-scattering component.
TLDR
The error in Lr(r) caused by ignoring surface roughness is shown to be the same order of magnitude as that caused by uncertainties of +/- 15 mb in the surface atmospheric pressure or of +/- 50 Dobson units in the ozone concentration.
A simple, moderately accurate, atmospheric correction algorithm for SeaWiFS☆
Retrieval of the columnar aerosol phase function and single-scattering albedo from sky radiance over the ocean: simulations.
TLDR
It is found that the retrieved aerosol phase function and the single-scattering albedo are virtually error free if the vertical structure of the atmosphere is known and if the sky radiance and the aerosol optical thickness can be measured accurately.
Surface-roughness considerations for atmospheric correction of ocean color sensors. II: Error in the retrieved water-leaving radiance.
TLDR
Simulations are carried out to assess the error incurred when the CZCS-type algorithm is applied to a realistic ocean in which the surface is roughened by the wind, suggesting that in refining algorithms for future sensors more effort should be placed on dealing with the Rayleigh-aerosol interaction than on the roughness of the sea surface.
An algorithm for remote sensing of water color from space
The ocean color algorithm proposed in this paper takes into account the effects of Rayleigh and aerosol scattering. The inherent reflectance and the diffuse transmittance of the Rayleigh atmosphere
Removal of atmospheric effects from satellite imagery of the oceans.
  • H. Gordon
  • Environmental Science, Mathematics
    Applied optics
  • 1978
TLDR
Application of the proposed algorithm to correct the radiance at a wavelength lambda requires only the ratio of the aerosol optical thickness at lambda to that at about 750 nm and the accuracy to which the correction can be made is in detail.
Atmospheric effects in the remote sensing of phytoplankton pigments
We investigate the accuracy with which relevant atmospheric parameters must be estimated to derive phytoplankton pigment concentrations (chlorophyll a plus phaeophytin a ) of a given accuracy from
Coastal Zone Color Scanner atmospheric correction algorithm: multiple scattering effects.
TLDR
This study provides CZCS users sufficient information with which to judge the efficacy of the current algorithm with the current sensor and enables them to estimate the impact of the algorithm-induced errors on their applications in a variety of situations.
Turbidity of the atmosphere determined from satellite: Calculation of optimum viewing geometry
By numerical modeling, the variability of the upward emerging spectral radiance is investigated due to the variability of the optically acting atmospheric constituents (no clouds) and due to the
Measurements of atmospheric aerosol optical thickness over water using ERTS-1 data.
  • M. Griggs
  • Environmental Science, Physics
    Journal of the Air Pollution Control Association
  • 1975
TLDR
The ERTS-1 satellite offered the opportunity of determining the feasibility of monitoring the atmospheric aerosol optical thickness on a global basis, as suggested by theoretical studies, which showed a linear relationship between the upwelling earth-atmosphere radiance and the aerosol Optical thickness.
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