Despite the majority of US fatal and severe pedestrian injuries occurring at midblock locations, few communities have collected counts to understand pedestrian midblock exposure and crash rates. This study developed a midblock pedestrian crossing count protocol and applied it to 61 street segments in the City of Milwaukee, WI. We counted midblock and adjacent intersection pedestrian crossings manually from 24-h video recordings. Midblock pedestrian crossings were common: 46 of the segments (75%) averaged more than one per hour. Among 48 segments with complete counts for both the midblock and an adjacent intersection crossing zone, 15 (31%) had more crossings in the midblock zone. We estimate that 17% of all pedestrian crossings along these 48 segments were midblock. Using these counts, we developed a negative binomial direct demand model of midblock pedestrian crossing volumes in Milwaukee. Midblock volumes were positively associated with nearby job density, commercial retail properties, and bus stops and negatively associated with posted speed limit and nearby parks. We demonstrated the value of this model by calculating pedestrian crash rates for all of our study segments and by estimating pedestrian crossing volumes for 133 additional street segments along seven roadway corridors. Expanding these methods beyond Milwaukee could lead to improved understanding of midblock pedestrian volumes and crash rates, ultimately helping communities reduce midblock pedestrian injuries and fatalities.
National Highway Traffic Safety Administration (NHTSA). Fatality Analysis Reporting System (FARS) Encyclopedia. FARS Data Tables. 2025. https://www-fars.nhtsa.dot.gov/Main/index.aspx. Accessed June 15, 2025.
SchneiderR. J.United States Pedestrian Fatality Trends, 1977 to 2016. Transportation Research Record: Journal of the Transportation Research Board, 2020. 2674: 1069–1083.
4.
CuiZ.NambisanS. S.Methodology for Evaluating the Safety of Midblock Pedestrian Crossings. Transportation Research Record: Journal of the Transportation Research Board, 2003. 1828: 75–82.
5.
ZhangC.ChenF.WeiY.Evaluation of Pedestrian Crossing Behavior and Safety at Uncontrolled Midblock Crosswalks with Different Numbers of Lanes in China. Accident Analysis & Prevention, Vol. 123, 2019, pp. 263–273.
ZegeerC. V.NaborsD.LagerweyP.PEDSAFE 2013: Pedestrian Safety Guide and Countermeasure Selection System. Prepared for the Federal Highway Administration, Office of Safety. 2013. http://www.pedbikesafe.org/pedsafe/. Accessed June 10, 2025.
FitzpatrickK.AvelarR.PrattM.BrewerM. A.RobertsonJ.LindheimerT.MilesJ.Evaluation of Pedestrian Hybrid Beacons and Rapid Flashing Beacons. No. FHWA-HRT-16-040. Federal Highway Administration, Turner-Fairbank Highway Research Center, McLean, VA, 2016.
10.
KadaliB. R.VedagiriP.Proactive Pedestrian Safety Evaluation at Unprotected Midblock Crosswalk Locations Under Mixed Traffic Conditions. Safety Science, Vol. 89, 2016, pp. 94–105.
11.
TezcanH. O.ElmorssyM.AksoyG.Pedestrian Crossing Behavior at Midblock Crosswalks. Journal of Safety Research, Vol. 71, 2019, pp. 49–57.
12.
Transportation Research Board Bicycle and Pedestrian Data Subcommittee. Beyond Collecting Counts: New and Emerging Data Practices, Conversations with Colleagues: May Meeting, Online, May 20, 2025. Background Information available online, June 19, 2025. 2025. https://sites.google.com/site/bikepeddata/conversations-with-colleagues.
13.
GeedipallyS. R.Estimating Pedestrian Crossing Volumes and Crashes at Midblock Locations. Transportation Research Record: Journal of the Transportation Research Board, 2022. 2676: 648–656.
14.
KumferW.ThomasL.SandtL.LanB.Midblock Pedestrian Crash Predictions in a Systemic, Risk-Based Pedestrian Safety Process. Transportation Research Record: Journal of the Transportation Research Board, 2019. 2673: 420–432.
SchneiderR. J.HemzeN.BarbeeH.SveenC.ThorneK.OgunniyiO. E.Mid-Block Pedestrian Crossing Exposure: Count Protocol and Database. University of Wisconsin-Milwaukee, Center for Pedestrian and Bicyclist Safety University Transportation Center, Project 24UWM04, 2025.
Wisconsin Traffic Operations and Safety (TOPS) Laboratory. The WisTransPortal Data Hub [Information System]. 2024. http://transportal.cee.wisc.edu/. Accessed June 10, 2025.
21.
SingletonP. A.ParkK.LeeD. H.Varying Influences of the Built Environment on Daily and Hourly Pedestrian Crossing Volumes at Signalized Intersections Estimated from Traffic Signal Controller Event Data. Journal of Transport Geography, Vol. 93, 2021, p. 103067.
22.
SchneiderR. J.SchmitzA.QinX.Development and Validation of a Seven-County Regional Pedestrian Volume Model. Transportation Research Record: Journal of the Transportation Research Board, 2021. 2675: 352–368.
23.
SobreiraL. T. P.HellingaB.Comparing Direct Demand Models for Estimating Pedestrian Volumes at Intersections and Their Spatial Transferability to Other Jurisdictions. Transportation Research Record: Journal of the Transportation Research Board, 2023. 2677: 260–271.
24.
LeM.GeedipallyS. R.FitzpatrickK.AvelarR. E.Estimating Pedestrian Volumes for Signalized and Stop-Controlled Intersections. Transportation Research Record: Journal of the Transportation Research Board, 2020. 2674: 799–808.
25.
JacobsenP. L.Safety in Numbers More Walkers and Bicyclists, Safer Walking and Bicycling. Injury Prevention, Vol. 9, 2003, pp. 205–209.
26.
SchneiderR. J.VargoJ.SanatizadehA.Comparison of US Metropolitan Region Pedestrian and Bicyclist Fatality Rates. Accident Analysis & Prevention, Vol. 106, 2017, pp. 82–98.
27.
SandersR. L.SchneiderR. J.ProulxF. R.Pedestrian Fatalities in Darkness: What do We Know, and What Can be Done?Transport Policy, Vol. 120, 2022, pp. 23–39.
28.
ThomasL.KumferW.LangK.ZegeerC.SandtL.LanB.NordbackK., et al. Systemic Pedestrian Safety Analysis: Contractor’s Technical Report. NCHRP Project 17-73. National Cooperative Highway Research Program, Transportation Research Board of The National Academies of Science, Engineering, and Medicine, Washington, DC, 2018. https://onlinepubs.trb.org/onlinepubs/nchrp/nchrp_rpt_893_Contractor.pdf. Accessed June 10, 2025.
