Abstract
Rapid changes in microbial water quality in surface waters pose challenges for production of safe drinking water. If not treated to an acceptable level, microbial pathogens present in the drinking water can result in severe consequences for public health. The aim of this paper was to evaluate the suitability of data-driven models of different complexity for predicting the concentrations of E. coli in the river Göta älv at the water intake of the drinking water treatment plant in Gothenburg, Sweden. The objectives were to (i) assess how the complexity of the model affects the model performance; and (ii) identify relevant factors and assess their effect as predictors of E. coli levels. To forecast E. coli levels one day ahead, the data on laboratory measurements of E. coli and total coliforms, Colifast measurements of E. coli, water temperature, turbidity, precipitation, and water flow were used. The baseline approaches included Exponential Smoothing and ARIMA (Autoregressive Integrated Moving Average), which are commonly used univariate methods, and a naive baseline that used the previous observed value as its next prediction. Also, models common in the machine learning domain were included: LASSO (Least Absolute Shrinkage and Selection Operator) Regression and Random Forest, and a tool for optimising machine learning pipelines – TPOT (Tree-based Pipeline Optimization Tool). Also, a multivariate autoregressive model VAR (Vector Autoregression) was included. The models that included multiple predictors performed better than univariate models. Random Forest and TPOT resulted in higher performance but showed a tendency of overfitting. Water temperature, microbial concentrations upstream and at the water intake, and precipitation upstream were shown to be important predictors. Data-driven modelling enables water producers to interpret the measurements in the context of what concentrations can be expected based on the recent historic data, and thus identify unexplained deviations warranting further investigation of their origin.
Highlights
The aim of this paper was to evaluate the suitability of data-driven models of different complexity for predicting the concentrations of E. coli in the river Göta älv at the water intake of the drinking water treatment plant in Gothenburg, Sweden
Rapid changes in microbial water quality in surface waters complicate the optimisation of the water treatment at the drinking water treatment plants
Changes in the microbial water quality of surface water are often caused by heavy rainfall leading to wastewater discharges from sewer systems and increased runoff from grazing areas and agricultural fields
Summary
Rapid changes in microbial water quality in surface waters complicate the optimisation of the water treatment at the drinking water treatment plants. If not treated to an acceptable level, microbial pathogens still present in the drinking water can result in severe consequences for public health as they may cause waterborne disease outbreaks (WHO, 2017). Waterborne outbreaks could cause lower trust from consumers, increase their perceived risk, and decrease their acceptance for drinking water (Bratanova et al, 2013). It is of value to predict and forecast the microbial concentrations in the incoming water to the drinking water treatment plant to be able to implement measures, e.g., use an alternative water source or optimize the treatment processes
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