Abstract
Abstract Machine learning (ML) methods are nowadays widely used to automate geophysical study. Some of ML algorithms are used to solve lithological classification problems during uranium mining process. One of the key aspects of using classical ML methods is causing data features and estimating their influence on the classification. This paper presents a quantitative assessment of the impact of expert opinions on the classification process. In other words, we have prepared the data, identified the experts and performed a series of experiments with and without taking into account the fact that the expert identifier is supplied to the input of the automatic classifier during training and testing. Feedforward artificial neural network (ANN) has been used as a classifier. The results of the experiments show that the “knowledge” of the ANN of which expert interpreted the data improves the quality of the automatic classification in terms of accuracy (by 5 %) and recall (by 20 %). However, due to the fact that the input parameters of the model may depend on each other, the SHapley Additive exPlanations (SHAP) method has been used to further assess the impact of expert identifier. SHAP has allowed assessing the degree of parameter influence. It has revealed that the expert ID is at least two times more influential than any of the other input parameters of the neural network. This circumstance imposes significant restrictions on the application of ANNs to solve the task of lithological classification at the uranium deposits.
Highlights
IntroductionProduction is carried out by in-situ leaching
Kazakhstan provides about 39 % of the world uranium production [1]
We aim to capture the nature of this phenomenon and to propose some measures to take it into account while applying artificial neural network (ANN) that is trained on input data assessed by experts
Summary
Production is carried out by in-situ leaching. In this method, uranium is extracted through a network of pumping-in and pumping-out wells, along which the leaching solution circulates. The purpose of the Geophysical Data Interpretation for Boreholes (GDIB) in this case is to determine the position of the ore body, and to identify the type and parameters of the enclosing rocks, their filtration properties. Since the extraction process is carried out by spreading the leaching solution, the isolation of impermeable and permeable rocks, the determination of their filtration properties are critically important. Accurate lithological interpretation can be carried out only taking into account all available data for the given well, on neighbouring wells, and taking into account the information obtained at the exploration stage [2]. An accurate interpretation requires experience and time, while the extraction technology requires prompt decisionmaking
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