An ensemble tree-based prediction of Marshall mix design parameters and resilient modulus in stabilized base materials
Created by W.Langdon from
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- @Article{KHAN:2023:conbuildmat,
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author = "Adnan Khan and Ju Huyan and Runhua Zhang and
Yu Zhu and Weiguang Zhang and Gao Ying and
Kamal Nasir Ahmad and Syed Khaliq Shah",
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title = "An ensemble tree-based prediction of Marshall mix
design parameters and resilient modulus in stabilized
base materials",
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journal = "Construction and Building Materials",
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volume = "401",
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pages = "132833",
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year = "2023",
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ISSN = "0950-0618",
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DOI = "doi:10.1016/j.conbuildmat.2023.132833",
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URL = "https://www.sciencedirect.com/science/article/pii/S0950061823025497",
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keywords = "genetic algorithms, genetic programming, gene
expression programming, Marshall mix design properties,
Resilient modulus prediction, Flexible pavement,
Tree-based ensemble method, SHAP analysis",
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abstract = "A flexible pavement with an adequate Marshall mix
design for the asphalt mixture surface layer(s) and
appropriate subbase/base design offers a proper
pavement structure for driving safety and
comfortability. The conventional approach of
calculating the Marshall mix design properties (e.g.,
stability and flow) and resilient modulus of base
materials typically requires laborious, expensive, and
time-consuming laboratory sample preparation and
testing, such as the Marshall stability test and
Resilient modulus test. Therefore, this study conducts
research on the application of tree-based ensemble
methods specifically, random forest (RFR) and eXtreme
gradient boosting regression (XGBR) to predict the
properties (mainly including Marshall stability, flow,
VMA, VFA, and unit weigh) of asphalt mix following
Marshall mix design and resilient modulus (Mr) of
stabilized aggregate base material. To develop the
prediction models, a comprehensive database was
established using existing literature. The performance
of the prediction models was evaluated using
statistical parameters, performance index (p), and
other suggested model performance criteria from
external research. Additionally, the Shapley Additive
exPlainations (SHAP) interpretation technique was
employed to explain the models. The analysis results
demonstrate that both RFR and XGBR methods have the
excellent fitting capability (R > 0.9). However, XGBR
has superior performance in predicting Marshall mix
properties and Mr value. Comparison with previous
research studies reveals that the proposed models show
superior performance than genetic programming-based
Marshall mix design models. The RFR model performs
approximately similar to ANN, while XGBR outperforms
ANN, and particle swarm optimization-extreme learning
machine-based models for Mr prediction. Furthermore,
the equation developed based on multi expression
programming for Mr value prediction exhibits superior
performance compared to previous research study gene
expression programming model",
- }
Genetic Programming entries for
Adnan Khan
Ju Huyan
Runhua Zhang
Yu Zhu
Weiguang Zhang
Gao Ying
Kamal Nasir Ahmad
Syed Khaliq Shah
Citations