Abstract
Total suspended solids (TSS) is an important environmental parameter to monitor in the Chesapeake Bay due to its effects on submerged aquatic vegetation, pathogen abundance, and habitat damage for other aquatic life. Chesapeake Bay is home to an extensive and continuous network of in situ water quality monitoring stations that include TSS measurements. Satellite remote sensing can address the limited spatial and temporal extent of in situ sampling and has proven to be a valuable tool for monitoring water quality in estuarine systems. Most algorithms that derive TSS concentration in estuarine environments from satellite ocean color sensors utilize only the red and near-infrared bands due to the observed correlation with TSS concentration. In this study, we investigate whether utilizing additional wavelengths from the Moderate Resolution Imaging Spectroradiometer (MODIS) as inputs to various statistical and machine learning models can improve satellite-derived TSS estimates in the Chesapeake Bay. After optimizing the best performing multispectral model, a Random Forest regression, we compare its results to those from a widely used single-band algorithm for the Chesapeake Bay. We find that the Random Forest model modestly outperforms the single-band algorithm on a holdout cross-validation dataset and offers particular advantages under high TSS conditions. We also find that both methods are similarly generalizable throughout various partitions of space and time. The multispectral Random Forest model is, however, more data intensive than the single band algorithm, so the objectives of the application will ultimately determine which method is more appropriate.
Highlights
Total suspended solids (TSS) is an important parameter to monitor in estuarine systems due to its ecological, economic, and human health impacts
This study investigates whether additional information can be gained from statistical and machine learning models that utilize multispectral Moderate Resolution Imaging Spectroradiometer (MODIS) information when predicting TSS in estuarine systems, using the Chesapeake Bay as a case study
The Random Forest model performed best out of the eight models and the single-band algorithm on the holdout validation dataset. It outperformed the single-band algorithm on the top 20th percentile of test data, but did not perform better on the lower 80th percentile. We found that both methods of TSS prediction were generalizable throughout space and time, with relative performance dependent on the error metric used for comparison
Summary
Total suspended solids (TSS) is an important parameter to monitor in estuarine systems due to its ecological, economic, and human health impacts. Many satellite-derived and in situ-measured radiance algorithms for estuarine TSS retrieval have been developed based on the observed correlation between TSS and reflectances in the red and near-infrared red (NIR) wavelengths [4,5,6,7,8,9,10,11,12,13,14,15,16] Use of these bands is a particular advantage for studies that use the Moderate Resolution Imaging Spectroradiometer (MODIS), due to the higher spatial resolution of those bands on MODIS. This can be useful in geographically complex estuarine environments with small-scale dynamics and regions of interest near the shoreline Many of these TSS algorithms are tuned to a specific site or region, since differences between water bodies in inorganic and organic particle types and sizes change the inherent optical properties (IOPs) of the water [17,18]
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