Utilizing contemporary machine learning techniques for determining soilcrete properties

Soilcrete is an innovative construction material made by combining naturally occurring earth materials with cement. It can be effectively used in areas where other construction materials are not readily available due to financial or environmental reasons since soilcrete is made from readily availabl...

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Bibliographic Details
Published in:Earth science informatics 2025, Vol.18 (1), p.176, Article 176
Main Authors: Inqiad, Waleed Bin, Khan, Muhammad Saud, Mehmood, Zohaib, Khan, Naseer Muhammad, Bilal, Muhammad, Sazid, Mohammed, Alarifi, Saad S.
Format: Article
Language:English
Subjects:
Aggregates
Algorithms
Artificial intelligence
Carbon dioxide
Cement
Civil engineering
Concrete mixing
Construction costs
Construction industry
Construction materials
Density
Earth and Environmental Science
Earth science
Earth Sciences
Earth System Sciences
Emissions
Gene expression
Graphical user interface
Greenhouse gases
Industrial development
Informatics
Information Systems Applications (incl.Internet)
Machine learning
Material properties
Mechanical properties
Metakaolin
Modulus of elasticity
Ontology
Permeability
Prediction models
Simulation and Modeling
Soil properties
Space Exploration and Astronautics
Space Sciences (including Extraterrestrial Physics
Strain analysis
User interface
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Summary:Soilcrete is an innovative construction material made by combining naturally occurring earth materials with cement. It can be effectively used in areas where other construction materials are not readily available due to financial or environmental reasons since soilcrete is made from readily available natural clay. It can also help to cut down the greenhouse gas emissions from the construction industry by encouraging the use of resources that are locally available. Thus, it is imperative to reliably predict different properties of soilcrete since the accurate determination of these properties is crucial for the widespread use of soilcrete materials. However, the laboratory determination of these properties is subjected to significant time and resource constraints. As a result, this research was undertaken to provide empirical prediction models for the density, shrinkage, and strain of soilcrete mixes using two machine learning algorithms: Gene Expression Programming (GEP) and Extreme Gradient Boosting (XGB). The analysis revealed that XGB-based predictions correlated more with real-life values than GEP having training R 2 = 0.999 for both density and shrinkage prediction and R 2 = 0.944 for strain prediction. Moreover, several explanatory analyses including individual conditional expectation (ICE) analysis and shapely analysis were done on the XGB model which showed that water-to-binder ratio, metakaolin content, and modulus of elasticity are some of the most important variables for forecasting soilcrete materials properties. Furthermore, an interactive graphical user interface (GUI) has been developed for effective utilization in civil engineering industry to forecast these properties of soilcrete materials.
ISSN:1865-0473
1865-0481
DOI:10.1007/s12145-024-01520-2