Abstract
The abundance of phytoplankton is generally estimated by measuring the chlorophyll-a concentration (Cchla), which is an important factor in photosynthesis and can be used to analyze the density and biomass of phytoplankton in the ecosystem. The band-ratio-based empirical or semi-analytical algorithms are operationally applied to retrieve Cchla in global oceans, which generally experience difficulties from the diversity of optical properties and the complexity of the radiative transfer equations in analytical analyses, respectively. With an attempt to develop an accurate Cchla retrieval model for the optically complex coastal and estuarine waters, this study aimed to explore the deep learning (DL) methods in satellite retrieval of Cchla. A two-stage convolutional neural network (CNN), named Cchla-Net, was proposed, which utilized the spectral information of remote sensing reflectances at MODIS/Aqua’s visible bands. In the first-stage phase, the Cchla-Net was pretrained by a set of remote sensing patches, in which the Cchla was generated from an existing model (OC3M). The pretrained results were than used as the initial values to refine the network with the synthetic oversampled in-situ dataset in the second-stage training phase. Using in-situ samples for training with the new initial values has a higher probability to reach the global optimum. The quantitative analyses showed that the two-stage training was more likely to achieve a global optimum in the optimization than the one-stage training. Matchups of the in-situ Cchla measurements were used to evaluate the retrieval models. Results showed that the proposed Cchla-Net produced obvious better performance than the empirical and semi-analytical algorithms, implying the DL method was more effective for optically complex waters with extremely high Cchla. This study provided an applicable method for remote sensing retrieval of Cchla, which should be helpful for studying the spatial distribution and temporal variability in the productive Pearl River estuary (PRE) waters.
Highlights
Accurate retrieval of Cchla from ocean color data is often an extremely challenging task in estuarine and coastal waters, due to the complex optical properties related to the inconstant and uncorrelated phytoplankton biomass, suspended sediments and colored dissolved organic matter (CDOM)
This study aimed to explore the potentials of deep learning (DL) in improving remote sensing retrieval of estuarine and coastal Cchla
A total of 15 pairs of matchups from all campaigns were used for extracting coeffion in-situ measurements for reducing uncertainty and bias due to systematic perturbations, cients of multilinear regression algorithm (MLR) adjustment and for the network testing independently
Summary
Chlorophyll-a concentration (Cchla ) is one of the key estuarine water quality parameters and serves as an essential indicator of ocean primary productivity [1]. Accurate retrieval of Cchla from ocean color data is often an extremely challenging task in estuarine and coastal waters, due to the complex optical properties related to the inconstant and uncorrelated phytoplankton biomass, suspended sediments and colored dissolved organic matter (CDOM). The currently available satellite-derived water quality products are restricted to optically significant materials [2], and the standard ocean algorithms have tended to be largely dispersed in specific regions [3].
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