Abstract
Protection of water environments is an important part of overall environmental protection; hence, many people devote their efforts to monitoring and improving water quality. In this study, a self-adapting selection method of multiple artificial neural networks (ANNs) using hyperspectral remote sensing and ground-measured water quality data is proposed to quantitatively predict water quality parameters, including phosphorus, nitrogen, biochemical oxygen demand (BOD), chemical oxygen demand (COD), and chlorophyll a. Seventy-nine ground measured data samples are used as training data in the establishment of the proposed model, and 30 samples are used as testing data. The proposed method based on traditional ANNs of numerical prediction involves feature selection of bands, self-adapting selection based on multiple selection criteria, stepwise backtracking, and combined weighted correlation. Water quality parameters are estimated with coefficient of determination R 2 ranging from 0.93 (phosphorus) to 0.98 (nitrogen), which is higher than the value (0.7 to 0.8) obtained by traditional ANNs. MPAE (mean percent of absolute error) values ranging from 5% to 11% are used rather than root mean square error to evaluate the predicting precision of the proposed model because the magnitude of each water quality parameter considerably differs, thereby providing reasonable and interpretable results. Compared with other ANNs with backpropagation, this study proposes an auto-adapting method assisted by the above-mentioned methods to select the best model with all settings, such as the number of hidden layers, number of neurons in each hidden layer, choice of optimizer, and activation function. Different settings for ANNS with backpropagation are important to improve precision and compatibility for different data. Furthermore, the proposed method is applied to hyperspectral remote sensing images collected using an unmanned aerial vehicle for monitoring the water quality in the Shiqi River, Zhongshan City, Guangdong Province, China. Obtained results indicate the locations of pollution sources.
Highlights
A fast and efficient computational method should be developed to quantitatively predict water contaminants because of the large area of contaminated water and the need for instant water monitoring.Water quality [1] parameters mainly include phosphorus, nitrogen [2], biochemical oxygen demand (BOD), chemical oxygen demand (COD), and chlorophyll a (Chla) [3,4]
This study develops a self-adapting artificial neural networks (ANNs) based on remote sensing data to predict the contents of nitrogen, phosphorus, BOD, COD, turbidity, and Chla [39] using the modified spectral reflectance of water collected with a ground-based analytical spectral device (ASD)
The content levels of phosphorus, nitrogen, COD, BOD, turbidity, and Chla range from 0.09 mg/L to 0.52 mg/L, from 0.09 mg/L to 5.37 mg/L, from 5.0 mg/L to 58.0 mg/L, from 1.0 mg/L
Summary
Water quality [1] parameters mainly include phosphorus, nitrogen [2], biochemical oxygen demand (BOD), chemical oxygen demand (COD), and chlorophyll a (Chla) [3,4]. Intensive growth of algae blocks the light needed by other aquatic life [7], demonstrating that low oxygen kills seagrass, fish, crabs, oysters, and other aquatic animals [6]. COD refers to organic pollutants at a site, such as chemicals, petroleum, solvents, and cleaning agents, forming as wastewater pollutants. These pollutants are spilled, mixed, and reaches stormwater, in which they are broken down and require an additional need for oxygen in water [9]. BOD and COD are associated with the amount of pollutants in water
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