Abstract
An approach to semianalytically derive waters' inherent optical properties (IOPs) from remote sensing reflectance ( R rs ) and at the same time to take into account the residual errors in satellite R rs is developed for open-ocean clear waters where aerosols are likely of marine origin. This approach has two components: (1) a scheme of combining a neural network and an algebraic solution for the derivation of IOPs, and (2) relationships between R rs residual errors at 670 nm and other spectral bands. This approach is evaluated with both synthetic and Sea-viewing Wide Field-of-view Sensor (SeaWiFS) data, and the results show that it can significantly reduce the effects of residual errors in R rs on the retrieval of IOPs, and at the same time remove partially the R rs residual errors for “low-quality” and “high-quality” data defined in this study. Furthermore, more consistent estimation of chlorophyll concentrations between the empirical blue-green ratio and band-difference algorithms can be derived from the corrected “low-quality” and “high-quality” R rs . These results suggest that it is possible to improve both data quality and quantity of satellite-retrieved R rs over clear open-ocean waters with a step considering the spectral relationships of the residual errors in R rs after the default atmospheric correction procedure and without fixing R rs at 670 nm to one value for clear waters in a small region such as 3 × 3 box.
Original language | American English |
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Journal | Journal of Geophysical Research: Oceans |
Volume | 121 |
DOIs | |
State | Published - Jan 1 2016 |
Keywords
- neural network
- QAA
- residual error
- SeaWiFS
- inherent optical properties
- OCI
Disciplines
- Life Sciences