Abstract
Pumping tests are very important means for investigating aquifer properties; however, interpreting the data using common analytical solutions become invalid in complex aquifer systems. The paper aims to explore the potential of machine learning methods in retrieving the pumping tests information in a field site in the Democratic Republic of Congo. A newly planned mining site with a pumping test of three pumping wells and 28 observation wells over one month was chosen to analyze the significance of machine learning methods in the pumping test analysis. Widely used machine learning methods, including correlation, cluster, time-series analysis, artificial neural network (ANN), support vector machine (SVR), random forest (RF) method, and linear regression, are all used in this study. Correlation and cluster analyses among wells provide visual pictures of possible hydraulic connections. The pathway with the best permeability ranges from the depth of 250 m to 350 m. Time-series analysis perfectly captured changes of drawdowns within the three pumping wells. The RF method is found to have the higher accuracy and the lower sensitivity to model parameters than ANN and SVR methods. The coupling of the linear regressive model and analytical solutions is applied to estimate hydraulic conductivities. The results found that ML methods can significantly and effectively improve our understanding of pumping tests by revealing inherent information hidden in those tests.
Highlights
Groundwater is one of the most valuable natural resources, and accounts for over 66% of freshwater resources in the world [1]
The multilayered observation wells are not at the same depths as the boreholes, the contour map of maximum drawdowns for all wells is firstly projected in the same plain
The PR coefficient only demonstrates the relationship of groundwater level changes for two wells
Summary
Groundwater is one of the most valuable natural resources, and accounts for over 66% of freshwater resources in the world [1]. Pumping tests play an important role in aquifer property estimations and groundwater resource evaluations. Different analytical solutions [2], such as Theis solutions for confined aquifers and Hantush-Jacob solutions for leaky aquifers, have been developed to provide methods to interpret pumping test data. These solutions may become invalid in complex hydrogeological conditions, due to the limitation of their strict assumptions. In the context of the complexity of a groundwater system in heterogeneous aquifers, machine learning methods have been progressively and successfully applied in groundwater studies [3], including groundwater level forecasting [4,5,6,7], parameter estimation [8,9,10,11] or optimization [12,13]
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