Internal Stability of Mechanically Stabilized Earth Wall Using Machine Learning Techniques

This paper proposes an AI-based prediction method for factor of safety (FOS) against rupture and pull-out failure and examines and compares the applicability and adaptability of k-nearest neighbor (KNN), random forest (RF), and extreme gradient boosting (XGBoost) in the reliability analysis of internal stability of mechanically stabilized earth wall. In order to predict FOS against rupture and pull-out failure, these three machine learning (ML) models are applied to 100 datasets, taking into account three crucial input parameters, namely, the depth of the reinforcement layer below the wall’s crest, the angle of internal friction of soil, and the unit weight of soil. A variety of performance indicators, including coefficient of determination (R²), variance account factor, Legate and McCabe’s index, A-10 index, root mean square error (RMSE), expanded uncertainty, mean absolute error, and median absolute, are engaged to assess the effectiveness of the well-established ML models. The results, which are based on performance metrics, indicate that XGBoost outperformed in both the two cases, i.e., rupture and pull-out, than the other proposed machine learning models in terms of predictive performance. This can be attributed to its highest R² = 0.999 and lowest RMSE = 0.002 (in case of rupture) and highest R² = 0.999 and lowest RMSE = 0.003 (in case of pull-out failure) during the training phase, as well as its highest value of R² = 0.864 and lowest value of RMSE = 0.102 (in case of rupture) and R² = 0.944 and RMSE = 0.054 (in case of pull-out failure) during the testing phase. Rank analysis, reliability analysis, regression plot, confusion matrix, and error matrix plot are the other tools used to assess the performance of the model. Using first-order second moment methods, the reliability index of the model is computed and compared to the actual value for both cases. Sensitivity analysis is also performed to regulate the effect of each input parameter on both outputs.

• Record URL:
  • https://doi.org/10.1007/s40515-024-00410-w
• Availability:
  • Find a library where document is available. Order URL: http://worldcat.org/issn/21967202
• Supplemental Notes:
  • © The Author(s), under exclusive licence to Springer Science+Business Media, LLC, part of Springer Nature 2024. Springer Nature or its licensor (e.g. a society or other partner) holds exclusive rights to this article under a publishing agreement with the author(s) or other rightsholder(s); author self-archiving of the accepted manuscript version of this article is solely governed by the terms of such publishing agreement and applicable law.
• Authors:
  • Mustafa, Rashid
  • Ahmad, Md Talib
• Publication Date: 2024-10

Language

• English

Media Info

• Media Type: Web
• Features: References;
• Pagination: pp 3204-3234
• Serial:
  • Transportation Infrastructure Geotechnology
  • Volume: 11
  • Issue Number: 5
  • Publisher: Springer Publishing
  • ISSN: 2196-7202
  • EISSN: 2196-7210
  • Serial URL: http://link.springer.com/journal/40515

Subject/Index Terms

• TRT Terms: Artificial intelligence; Earth walls; Geotechnical engineering; Machine learning; Sensitivity analysis; Stability (Mechanics)
• Subject Areas: Geotechnology; Transportation (General);

Filing Info

• Accession Number: 01933011
• Record Type: Publication
• Files: TRIS
• Created Date: Oct 9 2024 10:20AM