Abstract
In this study, two artificial neural network models (i.e., a radial basis function neural network, RBFN, and an adaptive neurofuzzy inference system approach, ANFIS) and a multilinear regression (MLR) model were developed to simulate the DO, TP, Chla, and SD in the Mingder Reservoir of central Taiwan. The input variables of the neural network and the MLR models were determined using linear regression. The performances were evaluated using the RBFN, ANFIS, and MLR models based on statistical errors, including the mean absolute error, the root mean square error, and the correlation coefficient, computed from the measured and the model-simulated DO, TP, Chla, and SD values. The results indicate that the performance of the ANFIS model is superior to those of the MLR and RBFN models. The study results show that the neural network using the ANFIS model is suitable for simulating the water quality variables with reasonable accuracy, suggesting that the ANFIS model can be used as a valuable tool for reservoir management in Taiwan.
Highlights
Water is an important resource for the survival and health of humans and ecosystems
The main objective of this study is to establish a multivariate linear regression (MLR) model and two artificial neural network models, including a radial basis function neural network (RBFN) and an adaptive neurofuzzy inference system (ANFIS), to simulate the dissolved oxygen (DO), the total phosphorus (TP), the chlorophyll a (Chl a) content, and the Secchi disk depth (SD), which are commonly used as indicators of the eutrophication of reservoirs
The selection of an appropriate set of input variables for the multilinear regression (MLR), RBFN, and ANFIS models is important for predicting the water quality variables in reservoirs [36]
Summary
Water is an important resource for the survival and health of humans and ecosystems. Assessing the water quality variables is needed to develop best planning and management for water resources [1, 2]. The definition of eutrophication is the nutrient enrichment which means the excessive phosphorus and nitrogen loads in lakes and reservoirs, resulting in a serious problem. The natural or artificial enrichment of inland water bodies can cause eutrophication with algal blooms to deteriorate the water quality for human use and the decrease of dissolved oxygen levels, resulting in adverse effects on fisheries. The application of some modeling techniques to predict the behavior of enriched water bodies allows for combating adverse effects [3,4,5]
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