http://orcid.org/0000-0001-9535-9910
References
- American Association of State Highway and Transportation Officials (AASHTO). (2011). A policy on geometric design of highways and streets. Washington, DC: Author.
- Abdel-aty, M. A., & Radwan, A. E. (2000). Modeling traffic accident occurrence and involvement. Accident Analysis and Prevention, 32, 633–642.
- Allison, P. D. (2014). Measure of fit for logistic regression. Washington, DC: SAS Globar Forum.
- American National Standard. (2007). Manual on classification of motor vehicle traffic accidents. Retrieved from https://crashstats.nhtsa.dot.gov/Api/Public/ViewPublication/07D16
- CFR. (2001). 23 CFR 450.200. Retrieved from https://www.gpo.gov/fdsys/granule/CFR-2001-title23-vol1/CFR-2001-title23-vol1-sec450-200
- Chang, L.-Y., & Chien, J.-T. (2013). Analysis of driver injury severity in truck-involved accidents using a non-parametric classification tree model. Safety Science, 51, 17–22.
- Chang, L.-Y., & Wang, H.-W. (2006). Analysis of traffic injury severity: An application of non-parametric classification tree techniques. Accident Analysis and Prevention, 38, 1019–1027.
- Federal Highway Administration (FWHA). (2010). A guide to developing quality crash modification factors. Vienna, VA: Federal Highway Administration USDOT. Retrieved from http://safety.fhwa.dot.gov
- Gross, F. (2006). A dissertation in civil engineering: Alternative methods for estimating safety effectiveness on rural, tow-lane highways: Case-control and cohort methods. The Pennsylvania State University.
- Gross, F., & Jovanis, P. P. (2007). Estimation of the safety effectiveness of lane and shoulder width: The case-control approach. Journal of Transportation Engineering, 133(6), 362–369.
- Gross, F., Jovanis, P. P., Eccles, K., & Chen, K.-Y. (2009, June). Safety evaluation of lane and shoulder width combinations on rural, two-lane, undivided roads. Washington, DC: Federal Highway Administration Research and Technology. Retrieved from https://www.fhwa.dot.gov/publications/research/safety/09032/
- Hadi, M. A., Aruldhas, J., Chow, L. F., & Wattleworth, J. A. (1995). Estimating safety effects of cross-section design for various highway types using negative binomial regression. Transportation Research Record, 1500, 169–177.
- Haleem, K., Gan, A., & Lu, J. (2013). Using multivariate adaptive regression splines (MARS) to develop crash modification factors for urban freeway interchange influence areas. Accident Analysis and Prevention, 55, 12–21.
- Harwood, D. W. (1990). Effective utilization of street width on urban arterials. National Cooperative Highway Research Program, 330, 43.
- Harwood, D. W., Rabbani, E. R., Richard, K. R., McGee, H. W., & Gittings, G. L. (2003). Systemwide impact of safety and traffic operations design decisions for 3R projects. Washington, DC: Transportation Research Record.
- Hauer, E., Council, F. M., & Mohammedshah, Y. (2004). Safety models for urban four-lane undivided road segments. Transportation Research Record, 1897, 96–105.
- Kashani, A. T., & Mohaymany, A. S. (2011). Analysis of the traffic injury severity on two-lane, two-way rural roads based on classification tree models. Safety Science, 49, 1314–1320.
- Lao, Y., Zhang, G., Wang, Y., & Milton, J. (2013). Generalized nonlinear models for rearend crash risk analysis. Accident Analysis and Prevention, 62, 9–16.
- LCDS. (2015). London cycling design standards. Retrieved from https://consultations.tfl.gov.uk/cycling/draft-london-cycling-design-standards
- Lee, C., Abdel-aty, M., Park, J., & Wang, J.-H. (2015). Development of crash modification factors for changing lane width on roadway segments using generalized nonlinear models. Accident Analysis and Prevention, 76, 83–91.
- Loh, W.-Y. (2011). Classification and regression trees. WIREs Data Mining and Knowledge Discovery, 1, 14–23.
- National Complete Street Coalition. (2016, March). Smart Groth America: Making Neighborhoods Great Together. Retrieved from http://old.smartgrowthamerica.org/complete-streets/complete-streets-fundamentals/complete-streets-faq
- Potts, I. B., Harwood, D. W., & Richard, K. R. (2007). Relationship of lane width to safety on urban and suburban arterials. Transportation Research Record, 2023, 63–82.
- Rosey, F., Auberlet, J. M., Moisan, O., & Dupre, G. (2009). Impact of narrower lane width. Transportation Research Record, 2138, 112–119.
- Sando, T., & Moses, R. (2010). Integration transit into traditional neighborhood design policies-the influence of lane width on bus safety. Tallahassee, FL: Florida Department of Transportation-Transit Office.
- Sargent, M. (2015). Highway trust fund basics: A primer on federal surface transportation spending. Washington DC: The Heritage Foundation. Retrieved from http://www.heritage.org/research/reports/2015/05/highway-trust-fund-basics-a-primer-on-federal-surface-transportation-spending
- Stamatiadis, N., Pigman, J., Sacksteder, J., Ruff, W., & Lord, D. (2009). Impact of shoulder width and median width on safety. Washington, DC: Transportation Research Board.
- Strathman, J. G., Dueker, K. J., Zhang, J., & Williams, T. (2003). Analysis of design attributes and crashes on the Oregon highway system. Applied Health Economics & Health Policy, 2(4), 201–212.
- Wang, J., Hughes, W. E., & Stewart, R. (1998). Safety effects of cross-section design on rural multi-lane highways. Retrieved from http://onlinepubs.trb.org/onlinepubs/circulars/ec003/ch18.pdf
- Wang, Y., Nguyen, N. H., Levy, A. B. E., & Wu, Y.-J. (2008). Cost effective safety improvements for two-lane rural roads. Seattle, WA: The National Academics of Science Engineering and Medicine. Retrieved from https://trid.trb.org/view.aspx?id=850370
- Zeeger, C. V., Hummer, J., Reinfurt, D. W., & Hunter, W. (1987). Safety effects of cross-section design for two-lane roads. TRID, Trasnportation Research Records, 10, 207.