Robustness of Explainable Artificial Intelligence in Industrial Process Modelling
This work addresses the reliability of explainable AI for industrial applications, but it is incremental as it applies existing methods to a new domain with a novel scoring approach.
The paper evaluated the robustness of XAI methods like SHAP and LIME in industrial process modeling using an Electric Arc Furnace simulation, finding that ML model accuracy correlates with explanation correctness and revealing differences in methods' ability to predict true sensitivity.
eXplainable Artificial Intelligence (XAI) aims at providing understandable explanations of black box models. In this paper, we evaluate current XAI methods by scoring them based on ground truth simulations and sensitivity analysis. To this end, we used an Electric Arc Furnace (EAF) model to better understand the limits and robustness characteristics of XAI methods such as SHapley Additive exPlanations (SHAP), Local Interpretable Model-agnostic Explanations (LIME), as well as Averaged Local Effects (ALE) or Smooth Gradients (SG) in a highly topical setting. These XAI methods were applied to various types of black-box models and then scored based on their correctness compared to the ground-truth sensitivity of the data-generating processes using a novel scoring evaluation methodology over a range of simulated additive noise. The resulting evaluation shows that the capability of the Machine Learning (ML) models to capture the process accurately is, indeed, coupled with the correctness of the explainability of the underlying data-generating process. We furthermore show the differences between XAI methods in their ability to correctly predict the true sensitivity of the modeled industrial process.