Abstract
The spatial heterogeneity and nonlinearity exhibited by bio-optical relationships in turbid inland waters complicate the retrieval of chlorophyll-a (Chl-a) concentration from multispectral satellite images. Most studies achieved satisfactory Chl-a estimation and focused solely on the spectral regions from near-infrared (NIR) to red spectral bands. However, the optical complexity of turbid waters may vary with locations and seasons, which renders the selection of spectral bands challenging. Accordingly, this study proposes an optimization process utilizing available spectral models to achieve optimal Chl-a retrieval. The method begins with the generation of a set of feature candidates, followed by candidate selection and optimization. Each candidate links to a Chl-a estimation model, including two-band, three-band, and normalized different chlorophyll index models. Moreover, a set of selected candidates using available spectral bands implies an optimal composition of estimation models, which results in an optimal Chl-a estimation. Remote sensing images and in situ Chl-a measurements in Lake Kasumigaura, Japan, are analyzed quantitatively and qualitatively to evaluate the proposed method. Results indicate that the model outperforms related Chl-a estimation models. The root-mean-squared errors of the Chl-a concentration obtained by the resulting model (OptiM-3) improve from 11.95 to 6.37 , and the Pearson’s correlation coefficients between the predicted and in situ Chl- improve from 0.56 to 0.89.
Highlights
Detecting drastic changes in water quality is necessary to prevent unexpected environmental incidents
The Chl-a in situ samples from Lake Kasumigaura and medium-resolution imaging spectrometer (MERIS) images with the same acquisition data were used as test data, and the coefficient of determination R2 was adopted as the measurement of regression fitness
This study provides an accurate satellite Chl-a model of turbid water by using optimal feature generation and selection based on feature generation from the two-band, three-band, and normalized difference chlorophyll index (NDCI) models
Summary
Detecting drastic changes in water quality is necessary to prevent unexpected environmental incidents. Conventional water sampling methods are reliable but are ineffective in identifying detailed spatial variations of water quality, which renders comprehensive management infeasible [1,2,3]. Remote sensing techniques have been proven effective in the selection of aquaculture sites and the qualitative measurement of regional water parameters, including suspended sediment, chlorophyll-a (Chl-a), and pollutant loads [4,5,6]. Kuhn et al [7] used Landsat-8 and Sentinel-2 aquatic remote sensing reflectance products to estimate turbidity over the Amazon, Columbia, and Mississippi rivers. The ease of remote sensing techniques relies on the determination of the optical properties of water bodies.
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