https://orcid.org/0000-0001-8666-6900
References
- Batioja-Alvarez, D., et al., 2018. Statistical distributions of pavement damage associated with overweight vehicles: methodology and case study. Transportation Research Record, 2672 (9), 229–241.
- Fathi, A., et al., 2019. Parametric study of pavement deterioration using machine learning algorithms. In: Proceeding of international airfield and highway pavements conference 2019: innovation and sustainability in highway and airfield pavement technology. Chicago IL, USA: American Society of Civil Engineers (ASCE), 31–41.
- Federal Highway Administration, 2015. Report to congress on compilation of existing state truck size and weight limit laws. Available from: https://ops.fhwa.dot.gov/freight/policy/rpt_congress/truck_sw_laws/app_a.htm#nj.
- Federal Highway Administration, 2017. Policy information. Available from: https://www.fhwa.dot.gov/ohim/ohimvtis.cfm [Accessed 27 April 2020].
- Gong, H., et al., 2018. Use of random forests regression for predicting iri of asphalt pavements. Construction and Building Materials, 189, 890–897.
- Gungor, O.E., et al., 2019. Development of an overweight vehicle permit fee structure for Illinois. Transport Policy, 82, 26–35.
- Haider, S.W., and Harichandran, R.S, 2009. Effect of axle load spectrum characteristics on flexible pavement performance. Transportation Research Record, 2095 (1), 101–114.
- Haider, S.W., Harichandran, R.S., and Dwaikat, M.B, 2009. Closed-form solutions for bimodal axle load spectra and relative pavement damage estimation. Journal of Transportation Engineering, 135 (12), 974–983.
- Hajek, J.J., et al., 1985. Performance prediction for pavement management. In: Proceeding of North American pavement management conference, Toronto, Ontario, Canada.
- Hastie, T., Tibshirani, R., and Friedman, J, 2009. The element of statistical learning: data mining, interface, and prediction. 2nd ed. Springer New York.
- Huang, Y.H., 1993. Pavement analysis and design. Englewood Cliffs: Prentice Hall.
- Inkoom, S., et al., 2019a. Pavement crack rating using machine learning frameworks: partitioning, bootstrap forest, boosted trees, naive bayes, and k -nearest neighbors. Journal of Transportation Engineering, Part B: Pavements, 145 (3), 04019031.
- Inkoom, S., et al., 2019b. Prediction of the crack condition of highway pavements using machine learning models. Structure and Infrastructure Engineering, 15 (7), 940–953.
- Jackson, N.C., Deighton, R., and Huft, D.L, 1996. Development of pavement performance curves for individual distress indexes in South Dakota based on expert opinion. Transportation Research Record, 1524, 130–136.
- Jasim, A., Wang, H., and Bennert, T, 2019. Evaluation of clustered traffic inputs for mechanistic-empirical pavement design: case study in New Jersey. Transportation Research Record, 2673 (11), 332–348.
- Kohavi, R., 1995. A study of cross-validation and bootstrap for accuracy estimation and model selection. In: Proceeding of 14th international joint conference on artificial intelligence, Montreal, Quebec Canada, IJCAI Organization, 1137–1143.
- Li, Z., and Sinha, K, 2000. A methodology to estimate load and non-load shares of highway pavement routine maintenance and rehabilitation expenditures. West Lafayette, IN: FHWA/IN/JTRP-2000/4.
- Marcelino, P., et al., 2019. Machine learning approach for pavement performance prediction. International Journal of Pavement Engineering, 22 (3), 341–354.
- Matlab, 2010. Version 7.10.0 (r2010a). Natick, MA: The MathWorks Inc.
- Ong, G.P., Nantung, T., and Sinha, K.C, 2010. Indiana pavement preservation program. West Lafayette, IN: FHWA/IN/JTRP-2010/14.
- Rys, D., Judycki, J., and Jaskula, P, 2016. Analysis of effect of overloaded vehicles on fatigue life of flexible pavements based on weigh in motion (WIM) data. International Journal of Pavement Engineering, 17 (8), 716–726.
- Schlotjes, M.R., et al., 2015. Using support vector machines to predict the probability of pavement failure. Proceedings of the Institution of Civil Engineers: Transport, 168 (3), 212–222.
- Titi, H.H., Coley, N.J., and Latifi, V, 2018. Evaluation of pavement performance due to overload single-trip permit truck traffic in Wisconsin. Advances in Civil Engineering, 2018, 1–11.
- Üstün, B., Melssen, W.J., and Buydens, L.M.C, 2006. Facilitating the application of support vector regression by using a universal Pearson vii function based kernel. Chemometrics and Intelligent Laboratory Systems, 81 (1), 29–40.
- Vapnik, V., 2000. The nature of statistical learning theory, 2nd, Springer-VerlagBerlin, Heidelberg.
- Wang, H., et al., 2020. Life-cycle cost analysis of pay adjustment for initial smoothness of asphalt pavement overlay. Journal of Testing and Evaluation, 48 (2), 1350–1364.
- Wang, H., and Wang, Z, 2019. Deterministic and probabilistic life-cycle cost analysis of pavement overlays with different pre-overlay conditions. Road Materials and Pavement Design, 20 (1), 58–73.
- Wang, H., and Zhao, J, 2016. Development of overweight permit fee using mechanistic-empirical pavement design and life-cycle cost analysis. Transport, 31 (2), 156–166.
- Wang, H., Zhao, J., and Wang, Z., 2015. Impact of overweight traffic on pavement life using weigh-in-motion data and mechanistic-empirical pavement analysis. In: Proceeding of 9th international conference on managing pavement assets, Alexandria, VA, USA.
- Wu, D., et al., 2019. The assessment of damage to Texas highways due to oversize and overweight loads considering climatic factors. International Journal of Pavement Engineering, 20 (7), 853–865.
- Zhao, J.N., and Wang, H, 2020. Dynamic pavement response analysis under moving truck loads with random amplitudes. Journal of Transportation Engineering, Part B: Pavements, 146 (2), 04020020.
- Ziari, H., et al., 2016. Prediction of pavement performance: application of support vector regression with different kernels. Transportation Research Record, 2589, 135–145.