tuje

Turkish Journal of Engineering

2587-1366

Murat YAKAR

10.31127/tuje.1389994

Civil Construction Engineering

İnşaat Yapım Mühendisliği

An appraisal of statistical and probabilistic models in highway pavements

https://orcid.org/0000-0002-0228-8250

Agunwamba

Jonah

University of Nigeria

https://orcid.org/0000-0003-3515-8951

Tiza

Michael Toryila

University of Nigeria

https://orcid.org/0000-0002-9408-5302

Okafor

Fidelis

04 30 2024

8 2 300 329 11 13 2023 02 17 2024

2017

Turkish Journal of Engineering

Accurate performance prediction is crucial for safe and efficient travel on highway pavements. Within pavement engineering, statistical models play a pivotal role in understanding pavement behavior and durability. This comprehensive study critically evaluates a spectrum of statistical models utilized in pavement engineering, encompassing mechanistic-empirical, Weibull distribution, Markov chain, regression, Bayesian networks, Monte Carlo simulation, artificial neural networks, support vector machines, random forest, decision tree, fuzzy logic, time series analysis, stochastic differential equations, copula, hidden semi-Markov, generalized linear, survival analysis, response surface methodology and extreme value theory models. The assessment meticulously examines equations, parameters, data prerequisites, advantages, limitations, and applicability of each model. Detailed discussions delve into the significance of equations and parameters, evaluating model performance in predicting pavement distress, performance assessment, design optimization, and life-cycle cost analysis. Key findings emphasize the critical aspects of accurate input parameters, calibration, validation, data availability, and model complexity. Strengths, limitations, and applicability across various pavement types, materials, and climate conditions are meticulously highlighted for each model. Recommendations are outlined to enhance the effectiveness of statistical models in pavement engineering. These suggestions encompass further research and development, standardized data collection, calibration and validation protocols, model integration, decision-making frameworks, collaborative efforts, and ongoing model evaluation. Implementing these recommendations is anticipated to enhance prediction accuracy and enable informed decision-making throughout highway pavement design, construction, maintenance, and management. This study is anticipated to serve as a valuable resource, providing guidance and insights for researchers, practitioners, and stakeholders engaged in asphalt engineering, facilitating the effective utilization of statistical models in real-world pavement projects.

Model validation Pavement engineering Performance evaluation Predictive modelling Statistical models

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