https://orcid.org/0000-0003-4073-6170
References
- AASHTO, 1990. A policy on geometric design of highways and streets: 1990. Washington, D.C.: AASHTO.
- Anderson, D.A., et al., 1998. Improved surface drainage of pavements. Final report NCHRP Project 1-29, Transportation Research Board, Washington DC, USA.
- Cai, J., et al., 2020. Wide-area dynamic sensing method of water film thickness on asphalt runway. Journal of Testing and Evaluation, 48 (3), 2129–2143.
- Chen, S., et al., 2019. The global macroeconomic burden of road injuries: estimates and projections for 166 countries. The Lancet Planetary Health, 3 (9), e390–e398.
- Chesterton, J., Nancekivell, N., and Tunnicliffe, N., 2006. The use of the Gallaway formula for aquaplaning evaluation in New Zealand. New Zealand: NZIHT and Transit NZ 8th Annual Conference.
- Childs, E. C, 1971. Drainage of groundwater resting on a sloping bed. Water Resources Research, 7 (5), 1256–1263.
- Das, S., et al., 2020. Vehicle involvements in hydroplaning crashes: applying interpretable machine learning. Transportation Research Interdisciplinary Perspectives, 6, 100176.
- Ding, Y.M. and Wang, H., 2018. Evaluation of hydroplaning risk on permeable friction course using tire–water–pavement interaction model. Transportation Research Record, 2672 (40), 408–417.
- Ding, Y.M. and Wang, H., 2020. Computational investigation of hydroplaning risk of wide-base truck tyres on roadway. International Journal of Pavement Engineering, 21 (1), 122–133.
- Dupuit, J., 1863. Etudes Théoriques et Pratiques sur le mouvement des Eaux dans les canaux découverts et à travers les terrains perméables. 2nd ed. Paris: Dunod.
- Eck, B.J., Charbeneau, R.J., and Barrett, M.E., 2010. Drainage hydraulics of porous pavement: coupling surface and subsurface flow. Dissertation. University of Texas at Austin.
- FHWA, 2017. How do weather events impact roads? Washington, DC: U.S. Department of Transportation, Federal Highway Administration, Road Weather Management Program. Available from: https://ops.fhwa.dot.gov/weather/q1_roadimpact.htm
- Fwa, T.F. and Ong, G.P, 2008. Wet-pavement hydroplaning risk and skid resistance: analysis. Journal of Transportation Engineering, 134 (5), 182–190.
- Gallaway, B.M., et al., 1979. Pavement and geometric design criteria for minimizing hydroplaning. FHWA-RD-79-31 Final Report, Federal Highway Administration, USA.
- Gerthoffert, J., et al., 2014. Modelling of water flow and prediction of water depth on runways. Conference Proceeding of Airports in Urban Networks, Paris, France.
- Horne, W.B. and Dreher, R.C., 1963. Phenomena of pneumatic tire hydroplaning. NASA TN D-2-56. Hampton, VA: NASA Langley Research Center.
- Huebner, R.S., Reed, J.R., and Henry, J.J, 1986. Criteria for predicting hydroplaning potential. Journal of Transportation Engineering, 112 (5), 549–553.
- Ivan, J.N., et al., 2012. A statistical analysis of the effect of wet-pavement friction on highway traffic safety. Journal of Transportation Safety & Security, 4 (2), 116–136.
- Ivey, D.L., Lehtipuu, E.K., and Button, J.W., 1975. Rainfall and visibility: the view from behind the wheel, TTI-1-10-70-135-3 Research Report. Texas Transportation Institute, Texas A&M University.
- Jeong, J., 2008. A hydrodynamic diffusion wave model for stormwater runoff on highway surfaces at superelevation transitions. Doctoral dissertation. University of Texas at Austin.
- Kane, M. and Do, M.T, 2012. Kinematic wave approach to model water depth on road surfaces during and after rainfall events. International Journal of Pavement Engineering, 13 (5), 385–394.
- Katz, B., et al., 2012. Guidelines for the use of variable speed limit systems in wet weather. No. FHWA-SA-12-022. Federal Highway Administration, USA.
- Liu, X.Y., et al., 2019. Analysis of vehicle braking performance on wet pavement surface using an integrated tire-vehicle modelling approach. Transportation Research Record, 2673 (3), 295–307.
- Luo, W., Wang, K.C., and Li, L., 2019. Field test validation of water film depth (WFD) prediction models for pavement surface drainage. International Journal of Pavement Engineering, 20 (10), 1170–1181.
- Manfredi, J., et al., 2008. Road weather information system environmental sensor station siting guide, version 2.0. FHWA-JPO-09-012. Dept. of Transportation, Washington DC, USA.
- Mannering, F., 2007. Effects of interstate speed limits on driving speeds: some new evidence. In Compendium of papers CD-ROM, Transportation Research Board 86th Annual Meeting.
- Manning, R., et al., 1890. On the flow of water in open channels and pipes. Transactions of the Institution of Civil Engineers of Ireland, 20, 161–207.
- McGovern, C., Rusch, P., and Noyce, D.A., 2011. State practices to reduce wet weather skidding crashes. Publication FHWA-SA-11-21, Washington, DC: Federal Highway Administration. U.S. Department of Transportation.
- Monjo, R., 2016. Measure of rainfall time structure using the dimensionless n-index. Climate Research, 67 (1), 71–86.
- Moussa, R. and Bocquillon, C., 2000. Approximation zones of the Saint-Venant equations f flood routing with overbank flow. Hydrology and Earth System Sciences, 4 (2), 251–260.
- Ong, G.P. and Fwa, T.F, 2007. Prediction of wet-pavement skid resistance and hydroplaning potential. Transportation Research Record, 2005 (1), 160–171.
- Ong, G.P. and Fwa, T.F., 2010. Modeling skid resistance of commercial trucks on highways. Journal of Transportation Engineering, 136 (6), 510–517.
- Ong, G.P., Fwa, T.F., and Guo, J., 2005. Modeling hydroplaning and effects of pavement microtexture. Transportation research record, 1905 (1), 166–176.
- Praticò, F.G. and Vaiana, R., 2015. A study on the relationship between mean texture depth and mean profile depth of asphalt pavements. Construction and Building Materials, 101, 72–79.
- Reed, J.R. and Kibler, D.F., 1983. Hydraulic resistance of pavement surfaces. Journal of Transportation Engineering, 109 (2), 286–296.
- Shah, R.K. and London, A.L., 1978. Laminar flow forced convection in ducts. New York: Academic Press.
- Srirangam, S.K., et al., 2014. Safety aspects of wet asphalt pavement surfaces through field and numerical modeling investigations. Transportation Research Record, 2446, 37–51.
- Sun, Y., et al., 2019. Deriving intensity–duration–frequency (IDF) curves using downscaled in situ rainfall assimilated with remote sensing data. Geoscience Letters, 6 (1), 17.
- Tang, T., et al., 2019. A finite element study of rain intensity on skid resistance for permeable asphalt concrete mixes. Construction and Building Materials, 220, 464–475.
- Yassin, M., 2019. Steady state hydroplaning risk analysis and evaluation of unsteady state effects. Doctoral dissertation. University of South Florida.
- Yassin, M., Jayasooriya, W., and Gunaratne, M., 2013. Assessment of the reliability of predicting hydroplaning risk based on past hydroplaning accident data on the florida interstate system. Transportation research record, 2369 (1), 104–113.
- Zhou, H., et al., 2020. Optimization of tire tread pattern based on flow characteristics to improve hydroplaning resistance. Proceedings of the Institution of Mechanical Engineers, Part D: Journal of Automobile Engineering, 234 (13), 2961–2974.
- Zhu, X.Y., et al., 2020. Numerical analysis of hydroplaning behaviour by using a tire–water-film–runway model. International Journal of Pavement Engineering, 24, 1–17.