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This research introduces an integrated framework that combines Automated Machine Learning (AutoML) with Explainable Artificial Intelligence (XAI) techniques for the prediction of fatigue strength Δ σ c in welded transverse stiffener details. The methodology synergizes expert-guided as well as algorithmic feature engineering to ensure both, high accuracy and interpretability across five model variants ( M 1 - M 5 ). An initial data curation phase was conducted to clean and harmonize an extensive fatigue test database in accordance with EN 1993-1-9 as sound base for comparative AI model assessment. Ensemble learners (e.g. LightGBM, CatBoost) achieved test RMSE ≈ 30 MPa and R Test 2 ≈ 0 . 78 over the full stress range. While M 3 attained the best training fit ( R Train 2 = 0 . 917 ), M 5 showed superior generalization, especially in the 0–150 MPa domain (RMSE ≈ 12.7 MPa, R Test 2 ≈ 0 . 58 ). SHAP interpretability consistently highlighted stress ratio R , stress range Δ σ i , yield strength R e H , and TIG dressing treatment as dominant predictors, with geometric descriptors playing secondary roles. The results suggest that M 5 offers the best balance between performance and interpretability. This work demonstrates a physically grounded, scalable method for AI-augmented fatigue assessment in structural engineering. • Unified AutoML + XAI pipeline for fatigue strength prediction of welded stiffener. • AutoML tuned tree algorithms achieve best R² values on both, training and test set. • Combining expert knowledge with algorithm-generated interactions. • Explainability built-in via SHAP values reveals dominant fatigue drivers. • Δσ , post-treatment, R , R eH are ranked highest by SHAP, affirming fatigue characteristics.
Kraus et al. (Thu,) studied this question.