tools for pedestrian and bicycle safety and exposure analysis › pdf ›...
TRANSCRIPT
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Tools for Pedestrian and Bicycle Safety andExposure Analysis
David Ragland, Founding Director, UCBerkeley SafeTRECJohn Bigham, GIS Program Manager,SafeTRECRobert Schneider, Researcher, SafeTREC
June 5, 1 pm
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Today’s Presentation Introduction and housekeepingAudio issues? Dial into the phone line instead of using
“mic & speakers”PBIC Trainings and Webinars
http://www.walkinginfo.orgRegistration and Archives at
http://walkinginfo.org/webinarsQuestions at the end
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Webinar
Tools for Pedestrian and BicycleSafety and Exposure Analysis
Tuesday, June 5, from 10-11:30am (PDT)
Introduction
David Ragland, UC Berkeley SafeTRECwww.tsc.berkeley.edu
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Topics
SafeTREC (Overview) Pedestrian and Bicyclist Safety (Examples) Data Reports and Data Tools (Examples) Data steps for pedestrian and bicyclist safety
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SafeTREC
Founded in 2000 with a grant from OTS to reduce trafficfatalities and injuries through multi-disciplinary collaboration ineducation, technical assistance, and outreach.
UC Partners include Public Health, Transportation Engineering,City and Regional Planning
Funders have included NHTSA, OTS, Caltrans, local cities,agencies, foundations
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Topics
SafeTREC (Overview) Pedestrian and Bicyclist Safety (Examples) Data Reports and Data Tools (Examples) Data steps for pedestrian and bicyclist safety
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Safe Routes to School Safety and MobilityAnalysis: Report to the California Legislature
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k Fatal Severe Injury Minor Injury
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Land Use ZonesAdjacent Blocks North
Adjacent Blocks South
Adjacent Blocks West
Campus Park
Hill Campus
Lawrence Berkeley National Laboratory
Southside/Clark Kerr Campus
UC Campus Periphery Project
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Barriers to Transit among Seniors
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Topics
SafeTREC (Overview) Pedestrian and Bicyclist Safety (Examples) Data Reports and Data Tools (Examples) Data steps for pedestrian and bicyclist safety
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Strategic Highway Safety Plan(Data Support Contract)
Roles Data Support
Provide standard and customized data analysesto each Challenge Area
5% Report Local Roads
Challenge area participation
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SHSP Version 2
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5% Report
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Continuous Risk Profile (CRP)
Continuous Risk Profile (CRP) DemonstrationWebinar for Caltrans District Leaders
Background: Many existing methods for detecting collisionconcentration locations (such as the conventional slidingmoving window approach) require segmentation of roadwaysand assume traffic collision data are spatially uncorrelated,resulting in false positives and false negatives.
CRP Capabilities:• does not require segmentation of roadways• spatial correlation in the collision data does not affect results• lower false positive rates• proactive identification of locations• plots are highly reproducible over the years• can capture “spillover benefit” of countermeasures• simple to use.
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Topics
SafeTREC (Overview) Pedestrian and Bicyclist Safety (Examples) Data Reports and Data Tools (Examples) Data steps for pedestrian and bicyclist safety
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Data steps for pedestrian andbicyclist safety
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Areas Examples from SafeTREC Presenter
1. Crash/injury data TIMS (geocoding) John
2. Data access Public Access to TIMS John
3. Pedestrian/bicyclevolume
Location-based analyses Bob
4. Hazard assessment Bayesian analysis, ContinuousRisk Profile
5. Causal analysis /countermeasureassessment
Collision modification factors
6. Benefit/cost Safety Index John
7. Integration with largerroadway data systems
Integrate active transportationdata with Caltrans data system
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PBIC Webinar—Tools for Pedestrian and BicycleSafety and Exposure Analysis
John [email protected]
Safe Transportation Research and Education CenterUniversity of California, Berkeley
www.safetrec.berkeley.edu
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Topics
• Overview of TIMS• Accessing and visualizing pedestrian and
bicycle collision data in TIMS– SWITRS Query & Map– SWITRS GIS Map
• Benefit-cost calculator for safetycountermeasures
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Transportation Injury Mapping System (TIMS)
• Provides data and mapping analysis tools andinformation for traffic safety related research,policy and planning.
• Free account application, open to everyone• http://tims.berkeley.edu
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SWITRS
• California Statewide Integrated TrafficRecords System
• Maintained by California Highway Patrol• Approximately 200,000 injury collisions each
year
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SWITRS Query & Map Tool
• Data query focused application– Quick results, quick refresh
• One page summary statistics• Download collision, party, victim files• Google Maps collision display
– 5,000 collisions limit– Collision points clustered until zoomed in
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SWITRS GIS Map
• Map-centric collision viewing with other datalayers (census tracts, TAZ, schools, etc.)
• Same collision query UI as Query & Map tool• 1,000 collisions display limit• Focused collision spatial selection tools
– Drawing– Buffer (intersection or corridor)– Region (TAZ, census tract, zip code)
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TIMS Mapping Applications• DEMO
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Benefit-Cost Calculator• Evaluate benefit-cost of potential safety
countermeasures• Benefit = reduction in comprehensive collision costs• Cost = construction costs
• Required for agencies to use that are applying forHighway Safety Improvement Program (HSIP)funds in California
• Includes pedestrian and bicycle specificcountermeasures
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Benefit-Cost Calculator• DEMO
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Local Roadway Safety Manual• Partnership of Caltrans, FHWA and
SafeTREC• Great resource for conceptual guidance
– Identifying safety issues– Safety data analysis– Countermeasures selection and b/c analysis
• http://www.dot.ca.gov/hq/LocalPrograms/HSIP/apply_now.htm
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Import into Benefit-Cost Calculator
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Funding Support
• Funding for TIMS was provided by a grant fromthe California Office of Traffic Safety, through theNational Highway Traffic Safety Administration.
• Funding for the B/C Calculator provided by theCaltrans Division of Local Assistance
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Questions?
• Thank you!
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Pedestrian & Bicycle VolumeModeling for Crash Risk Analysis
Robert Schneider, Ph.D.UC Berkeley Safe Transportation Research & Education Center
PBIC Webinar—June 2012
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How Many People are Walking & Bicycling?
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Where are People Walking & Bicycling?
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What Types of Locations have the GreatestRisk of Pedestrian or Bicycle Crashes?
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Pedestrian Crash Analysis
MainlineRoadway
IntersectingRoadway
ReportedPedestrian
Crashes(1996-2005)
MissionBoulevard
TorranoAvenue 5
Davis Street Pierce Avenue 4FoothillBoulevard D Street 1MissionBoulevard
JeffersonStreet 5
UniversityAvenue Bonar Street 7InternationalBoulevard 107th Avenue 2San PabloAvenue Harrison Street 2East 14thStreet
HasperianBoulevard 1
InternationalBoulevard 46th Avenue 3
Solano AvenueMasonicAvenue 2
Broadway 12th Street 5
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Pedestrian RISK Analysis
MainlineRoadway
IntersectingRoadway
EstimatedTotal Weekly
PedestrianCrossings
AnnualPedestrian
VolumeEstimate
Ten-YearPedestrian
VolumeEstimate
ReportedPedestrian
Crashes(1996-2005)
PedestrianRisk
(Crashes per10,000,000
crossings)
MissionBoulevard
TorranoAvenue 1,169 60,796 607,964 5 82.24
Davis Street Pierce Avenue 1,570 81,619 816,187 4 49.01FoothillBoulevard D Street 632 32,862 328,624 1 30.43MissionBoulevard
JeffersonStreet 5,236 272,246 2,722,464 5 18.37
UniversityAvenue Bonar Street 11,175 581,113 5,811,127 7 12.05InternationalBoulevard 107th Avenue 3,985 207,243 2,072,429 2 9.65San PabloAvenue Harrison Street 4,930 256,357 2,563,572 2 7.80East 14thStreet
HasperianBoulevard 3,777 196,410 1,964,102 1 5.09
InternationalBoulevard 46th Avenue 12,303 639,752 6,397,522 3 4.69
Solano AvenueMasonicAvenue 22,203 1,154,559 11,545,589 2 1.73
Broadway 12th Street 112,896 5,870,590 58,705,898 5 0.85
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Which Intersection Features areAssociated with Pedestrian Risk?
(Exploratory Research)Pedestrian Crossings (+)While intersections with more pedestriancrossings have more pedestrian crashes,there may be a “safety in numbers” effect(i.e., lower crash risk per crossing).
Motor Vehicle Volume (+)There may be a “danger in numbers” effectwith mainline motor vehicle volume, but needto explore the influence of congestion andspeed.
(Expected Effect*: 100% more pedestrian crossings, 49% more crashes)
(Expected Effect*: 100% more mainline AADT, >100% more crashes)
For more information on this study, see:Schneider, R.J., M.C. Diogenes, L.S. Arnold, V. Attaset, J. Griswold, and D.R. Ragland. “Association between RoadwayIntersection Characteristics and Pedestrian Crash Risk in Alameda County, California,” Transportation Research Record:Journal of the Transportation Research Board, Volume 2198, pp. 41-51, 2010.
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Which Intersection Features areAssociated with Pedestrian Risk?
Number of Right-Turn-Only Lanes (+)Intersections with more right-turn-only lanesmay have longer crossing distances and morecomplex interactions between drivers andpedestrians.
Number of Driveway Crossings (+)Intersections with more non-residentialdriveway crossings within 50 ft. may havemore conflict points; drivers may focus onentering or exiting motor vehicle lanes.
Medians (-)Mainline and cross-street legs with medianshave a refuge that allows pedestrians tocross one direction of traffic at a time, whichmay make crossing safer.
(Expected Effect*: 1 more right-turn-only lane, 53% more crashes)
(Expected Effect*: 1 more driveway crossing, 33% more crashes)
(Expected Effect*: Medians on mainline roadway crossings, 75% fewer crashes)
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Which Intersection Features areAssociated with Pedestrian Risk?
Number of Commercial Properties (+)Intersections with more commercialproperties within 0.1 miles may have moredrivers looking at signs and for parking; morepedestrians may cross between cars.
Percentage of Residents Under 18 (+)A greater percentage of young pedestrianswithin 0.25 miles may indicate that more ofthe people crossing are less experienced andhave higher risk crossing busy streets.
(Expected Effect*: 10 more commercial properties: 45% more crashes)
(Expected Effect*: 1% more residents under 18: 7% more crashes)
*Italics show the change in the expected number of pedestrian crashes at intersections with different features, inorder to provide a frame of reference. These numbers are based on the model, which reflects the 81 AlamedaCounty study intersections as a whole. The effect of any particular treatment is highly context specific.
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Many Demand Analysis Methods
• Traditional 4-step models• Direct counts & surveys• Sketch plan with expert-
defined weights• Network-based models• Location-based models
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The Traditional Four Step Model
Berkeley, CA Traffic Analysis Zones
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The Traditional Four Step Model
Berkeley, CA Traffic Analysis Zones
• Ignores trips that occur within zones(many short pedestrian & bicycle trips)
• Misses “secondary” trip modes (e.g.,walk from parking or walk to transit)
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81 Pedestrian & Bicycle Count Intersections
Pedestrian & Bicycle Counts
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Census/ACSData
Source: City of Seattle Bicycle Master Plan, 2007
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Census/ACS Data
Source: City of Alexandria, VA Pedestrian and Bicycle Mobility Plan, 2008
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Sketch Plan Methods
Source: Lancaster County Pedestrian and Bicycle Transportation Plan, Phase II, 2004
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Sketch Plan Methods
Source: Goodman, D., R. Schneider, and T. Griffiths. “Put Your Money where the People Are,” Planning, June 2009.
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Pedestrian Potential Analysis
Source: City of Alexandria, VA Pedestrian and Bicycle Mobility Plan, 2008
Sketch Plan Methods
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Network-Based Model: Space Syntax
Downtown BostonSource: Raford and Ragland.Pedestrian Volume Modeling ForTraffic Safety & ExposureAnalysis, 2005.
• Street and path networks(potential movementpatterns)
• Viewsheds• Fathom Visibility Graph
Analysis Software
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Network-Based Model: Clifton Maryland Ped Model
Source: Clifton, K.J., C.V. Burnier, S. Huang, M.W.Kang, and R. Schneider. “A Meso-Scale Model ofPedestrian Demand,” 2008.
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Location-Based Model
Source: Schneider R.J., L.S. Arnold, and D.R. Ragland. “A Pilot Model for Estimating Pedestrian IntersectionCrossing Volumes,” Transportation Research Record 2140, pp. 13-26, 2009.
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Approach: Develop a model to estimatepedestrian intersection crossing
volumes at different locations
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Location-Based Models
• Schneider, et al. San Francisco pedestrian (2012)• Miranda-Moreno, et al. Montreal pedestrian (2011)• Griswold, Medury, & Schneider, Alameda County bicycle
(2011)• Fehr & Peers, Santa Monica pedestrian & bicycle (2010)• Alta Planning + Design, San Diego pedestrian & bicycle
(2010)• Schneider, Arnold & Ragland, Alameda County pedestrian
(2009)• Liu & Griswold, San Francisco pedestrian (2009)• Pulugurtha & Repaka, Charlotte pedestrian (2008)
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Intersection-Based Pedestrian Models
Schneider, R.J., et al. “Development and Application of the San Francisco Pedestrian Intersection Volume Model” (2012)
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Intersection-Based Pedestrian Models
Schneider, R.J., et al. “Development and Application of the San Francisco Pedestrian Intersection Volume Model” (2012)
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Intersection-Based Pedestrian Models
Schneider, R.J., et al. “Development and Application of the San Francisco Pedestrian Intersection Volume Model” (2012)
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Intersection-Based Pedestrian Models
Schneider, R.J., et al. “Development and Application of the San Francisco Pedestrian Intersection Volume Model” (2012)
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Example: Development of the Alameda CountyPedestrian Volume Model
Source: Schneider R.J., L.S. Arnold, and D.R. Ragland. “A Pilot Model for Estimating Pedestrian IntersectionCrossing Volumes,” Transportation Research Record 2140, pp. 13-26, 2009.
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Pedestrian Model Development
• Sample of intersections along arterial andcollector roadways
• Pilot Model: April to June 2008 (N=50)• Validation: April to June 2009 (N=30)
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2008 Location Selection Process
• All Possible Intersections = 7,466• Choose 50 Intersections
– Ensure a wide variety of characteristics are represented– Ensure a wide geographic distribution
• Restrictions– No intersections with low pop. density, no grade separated
crossings, no intersections within ¼-mile of county line– Include at least 2 trail/roadway crossings & 3 CBD intersections
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Alameda County Intersection Map
50 Intersections Counted in 2008
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• Pedestrian crossings within 50 feet of each studyintersection
• 2-hour manual counts (Weekday & Saturday)• April to June 2008• Counts extrapolated and adjusted for land use & weather
Pilot Model Pedestrian Volume Data
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Example automated counter location: Broadway & 12th Street (Oakland)
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0.00%
0.20%
0.40%
0.60%
0.80%
1.00%
1.20%
1.40%12
AM
4 AM
8 AM
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“Typical” Alameda County Pedestrian Activity Pattern
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0.00%
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0.80%
1.00%
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4 AM
8 AM
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4 AM
8 AM
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4 AM
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“Typical” Alameda County Pedestrian Activity Pattern
2-hour countperiod
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One study intersection: Martin Luther King Jr. Wy. & 17th St., Oakland
Approximately 5,600 pedestrian crossings per week (Spring 2008)
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Alameda County Pilot ModelEstimated Weekly Pedestrian Crossings =
0.928 * Total population within 0.5-miles of theintersection
+ 2.19 * Total employment within 0.25-miles of theintersection
+ 98.4 * Number of commercial properties within 0.25-miles of the intersection
+54,600 * Number of regional transit stations within 0.10-miles of the intersection
- 4910 (Constant)
Adjusted R2 = 0.897Root Mean Squared Error = 5760Explanatory variables significant at 95% confidence interval
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Pilot Pedestrian VolumeModel Application
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Alameda County Pedestrian VolumeForecasting Spreadsheet
Mainline Roadway Intersecting Roadway City
Total populationwithin 1/2-mileradius3
Total employmentwithin 1/4-mileradius
Total number ofcommercialproperties within1/4-mile radius
Presence of regionaltransit station within1/10 mile(Yes = 1, No = 0)
EstimatedPedestrian Crossingsin a Typical Week5,6,7
Telegraph Avenue 59th Street Oakland 10270 610 27 0 8542
Notes :1. This i s a revised vers ion of the pi lot model of weekly pedestra in volumes at 50 intersections in Alameda County, CA. The model has a good fi t for the Alameda County s tudy data(adjusted-R2=0.900). Since the analys is was conducted on 50 intersections in Alameda County, CA, more research i s needed to refine the model equation and determine theappl icabi l i ty of the resul ts for other communities . The model equation i s : Es timated pedestrian intersection cross ings per week = 0.987 * Tota l population within 0.5-mi les of theintersection + 2.19 * Tota l employment within 0.25-mi les of the intersection + 71.1 * Number of commercia l reta i l properties within 0.25-mi les of the intersection + 49,300 * Numberof regional trans i t s tations within 0.10-mi les of the intersection - 4850. Deta i l s of the s tudy are provided in two papers : 1) Schneider, R.J., L.S. Arnold, and D.R. Ragland."Extrapolating Weekly Pedestrian Intersection Cross ing Volumes from 2-Hour Manual Counts ," UC-Berkeley Traffic Safety Center, Transportation Research Record, 2010, and 2)Schneider R.J., L.S. Arnold, and D.R. Ragland. “A Pi lot Model for Estimating Pedestrian Intersection Cross ing Volumes,” UC-Berkeley Traffic Safety Center, Transportation ResearchRecord, 2010.2. The pedestrian volume estimates produced by the model are intended for planning, priori ti zation, and safety analys is at the community, neighborhood, and corridor levels .Since the model provides rough estimates of pedestrian activi ty, actua l pedestrian counts should be used for s i te-level safety, des ign, and engineering analyses .3. The intersections selected for the s tudy did not include intersections in areas with very low population dens i ties (<50 people per square mi le). Therefore, the model i s notappropriate for intersections below this dens i ty threshold (i .e., the model does not apply i f there are fewer than 64 people within a 1/2-mi le radius ).4. The s tudy of Alameda County, CA found that land use characteris tics are the most important factors for predicting pedestrian activi ty. Roadway des ign factors , such as thepresence of s idewalks , median cross ing i s lands , curb radi i , or pedestrian cross ing s ignals may have minor effects on pedestrian volumes, but they are not as s igni ficant forpredicting pedestrian activi ty. However, roadway des ign factors are cri tica l for pedestrian safety and comfort. Roadways must be des igned to accommodate pedestrians of a l labi l i ties , regardless of volume.5. The model output i s an estimate of the number of pedestrian cross ings during a typica l 168-hour week (with an average seasonal volume). Pedestrian cross ings are countedeach time a pedestrian crosses any leg of the intersection (e.g., one person i s counted twice i f they cross the east leg and then the south leg of an intersection). Pedestrians donot need to cross completely ins ide the crosswalk; they are counted i f i f they cross within 50 feet of the intersection.6. The model may not perform wel l in locations close to specia l attractors , such as amusement parks , waterfronts , sports arenas , regional recreation areas , and major multi -use
Model OutputIntersection Identification Model Inputs 4
Pedestrian Intersection Crossing Volume ModelPilot Model--January 20091,2
Developed by Robert Schneider, Lindsay Arnold, and David RaglandUniversity of California Berkeley Safe Transportation Research & Education Center
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Mainline Roadway Intersecting Roadway City
Total populationwithin 1/2-mileradius3
Total employmentwithin 1/4-mileradius
Total number ofcommercialproperties within1/4-mile radius
Presence of regionaltransit station within1/10 mile(Yes = 1, No = 0)
EstimatedPedestrian Crossingsin a Typical Week5,6,7
Telegraph Avenue 59th Street Oakland 10270 610 27 0 8542Telegraph Avenue 59th Street Oakland 20540 1220 27 0 20014
Notes :1. This i s a revised vers ion of the pi lot model of weekly pedestra in volumes at 50 intersections in Alameda County, CA. The model has a good fi t for the Alameda County s tudy data(adjusted-R2=0.900). Since the analys is was conducted on 50 intersections in Alameda County, CA, more research i s needed to refine the model equation and determine theappl icabi l i ty of the resul ts for other communities . The model equation i s : Es timated pedestrian intersection cross ings per week = 0.987 * Tota l population within 0.5-mi les of theintersection + 2.19 * Tota l employment within 0.25-mi les of the intersection + 71.1 * Number of commercia l reta i l properties within 0.25-mi les of the intersection + 49,300 * Numberof regional trans i t s tations within 0.10-mi les of the intersection - 4850. Deta i l s of the s tudy are provided in two papers : 1) Schneider, R.J., L.S. Arnold, and D.R. Ragland."Extrapolating Weekly Pedestrian Intersection Cross ing Volumes from 2-Hour Manual Counts ," UC-Berkeley Traffic Safety Center, Transportation Research Record, 2010, and 2)Schneider R.J., L.S. Arnold, and D.R. Ragland. “A Pi lot Model for Estimating Pedestrian Intersection Cross ing Volumes,” UC-Berkeley Traffic Safety Center, Transportation ResearchRecord, 2010.2. The pedestrian volume estimates produced by the model are intended for planning, priori ti zation, and safety analys is at the community, neighborhood, and corridor levels .Since the model provides rough estimates of pedestrian activi ty, actua l pedestrian counts should be used for s i te-level safety, des ign, and engineering analyses .3. The intersections selected for the s tudy did not include intersections in areas with very low population dens i ties (<50 people per square mi le). Therefore, the model i s notappropriate for intersections below this dens i ty threshold (i .e., the model does not apply i f there are fewer than 64 people within a 1/2-mi le radius ).4. The s tudy of Alameda County, CA found that land use characteris tics are the most important factors for predicting pedestrian activi ty. Roadway des ign factors , such as thepresence of s idewalks , median cross ing i s lands , curb radi i , or pedestrian cross ing s ignals may have minor effects on pedestrian volumes, but they are not as s igni ficant forpredicting pedestrian activi ty. However, roadway des ign factors are cri tica l for pedestrian safety and comfort. Roadways must be des igned to accommodate pedestrians of a l labi l i ties , regardless of volume.5. The model output i s an estimate of the number of pedestrian cross ings during a typica l 168-hour week (with an average seasonal volume). Pedestrian cross ings are countedeach time a pedestrian crosses any leg of the intersection (e.g., one person i s counted twice i f they cross the east leg and then the south leg of an intersection). Pedestrians donot need to cross completely ins ide the crosswalk; they are counted i f i f they cross within 50 feet of the intersection.6. The model may not perform wel l in locations close to specia l attractors , such as amusement parks , waterfronts , sports arenas , regional recreation areas , and major multi -use
Model OutputIntersection Identification Model Inputs 4
Pedestrian Intersection Crossing Volume ModelPilot Model--January 20091,2
Developed by Robert Schneider, Lindsay Arnold, and David RaglandUniversity of California Berkeley Safe Transportation Research & Education Center
Alameda County Pedestrian VolumeForecasting Spreadsheet
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Mainline Roadway Intersecting Roadway City
Total populationwithin 1/2-mileradius3
Total employmentwithin 1/4-mileradius
Total number ofcommercialproperties within1/4-mile radius
Presence of regionaltransit station within1/10 mile(Yes = 1, No = 0)
EstimatedPedestrian Crossingsin a Typical Week5,6,7
Telegraph Avenue 59th Street Oakland 10270 610 27 0 8542Telegraph Avenue 59th Street Oakland 20540 1220 27 0 20014Telegraph Avenue 59th Street Oakland 20540 1220 100 0 25205
Notes :1. This i s a revised vers ion of the pi lot model of weekly pedestra in volumes at 50 intersections in Alameda County, CA. The model has a good fi t for the Alameda County s tudy data(adjusted-R2=0.900). Since the analys is was conducted on 50 intersections in Alameda County, CA, more research i s needed to refine the model equation and determine theappl icabi l i ty of the resul ts for other communities . The model equation i s : Es timated pedestrian intersection cross ings per week = 0.987 * Tota l population within 0.5-mi les of theintersection + 2.19 * Tota l employment within 0.25-mi les of the intersection + 71.1 * Number of commercia l reta i l properties within 0.25-mi les of the intersection + 49,300 * Numberof regional trans i t s tations within 0.10-mi les of the intersection - 4850. Deta i l s of the s tudy are provided in two papers : 1) Schneider, R.J., L.S. Arnold, and D.R. Ragland."Extrapolating Weekly Pedestrian Intersection Cross ing Volumes from 2-Hour Manual Counts ," UC-Berkeley Traffic Safety Center, Transportation Research Record, 2010, and 2)Schneider R.J., L.S. Arnold, and D.R. Ragland. “A Pi lot Model for Estimating Pedestrian Intersection Cross ing Volumes,” UC-Berkeley Traffic Safety Center, Transportation ResearchRecord, 2010.2. The pedestrian volume estimates produced by the model are intended for planning, priori ti zation, and safety analys is at the community, neighborhood, and corridor levels .Since the model provides rough estimates of pedestrian activi ty, actua l pedestrian counts should be used for s i te-level safety, des ign, and engineering analyses .3. The intersections selected for the s tudy did not include intersections in areas with very low population dens i ties (<50 people per square mi le). Therefore, the model i s notappropriate for intersections below this dens i ty threshold (i .e., the model does not apply i f there are fewer than 64 people within a 1/2-mi le radius ).4. The s tudy of Alameda County, CA found that land use characteris tics are the most important factors for predicting pedestrian activi ty. Roadway des ign factors , such as thepresence of s idewalks , median cross ing i s lands , curb radi i , or pedestrian cross ing s ignals may have minor effects on pedestrian volumes, but they are not as s igni ficant forpredicting pedestrian activi ty. However, roadway des ign factors are cri tica l for pedestrian safety and comfort. Roadways must be des igned to accommodate pedestrians of a l labi l i ties , regardless of volume.5. The model output i s an estimate of the number of pedestrian cross ings during a typica l 168-hour week (with an average seasonal volume). Pedestrian cross ings are countedeach time a pedestrian crosses any leg of the intersection (e.g., one person i s counted twice i f they cross the east leg and then the south leg of an intersection). Pedestrians donot need to cross completely ins ide the crosswalk; they are counted i f i f they cross within 50 feet of the intersection.6. The model may not perform wel l in locations close to specia l attractors , such as amusement parks , waterfronts , sports arenas , regional recreation areas , and major multi -use
Model OutputIntersection Identification Model Inputs 4
Pedestrian Intersection Crossing Volume ModelPilot Model--January 20091,2
Developed by Robert Schneider, Lindsay Arnold, and David RaglandUniversity of California Berkeley Safe Transportation Research & Education Center
Alameda County Pedestrian VolumeForecasting Spreadsheet
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36 Intersections Counted in 2009 (Red)
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Validation Analysis
• Compared pilot model estimated volume with“actual” volume at 30 intersections in 2009– Where did the Pilot model work well?– Where did the Pilot model overestimate volumes?– Where did the Pilot model underestimate volumes?
• Model tended to underestimate• Issue with some negative predictions at low-
volume intersections
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2009 Observed Volumesvs. Pilot Model Predictions
-5,000
0
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Weekly Pedestrian Volume "Observed" in 2009
Trendline forObserved vs.
Predicted Data
Line RepresentingPerfect Prediction(Observ. = Pred.)
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Variation in Pedestrian Volumes
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Variation in Pedestrian Volumes
• 5 Control Intersections
ID #
2008 WeeklyPedestrian Volume
based on Counts
2009 WeeklyPedestrian Volume
based on CountsAbsolute Difference
(2009 - 2008) Percent Difference1
50 315 310 -5 1.6%2650 15691 16113 422 2.7%9179 8342 7429 -913 12.3%9436 105297 88118 -17179 19.5%
499 5186 3448 -1738 50.4%1) Percent difference is calculated using the smaller number as the base value. If the modelvalue is greater than the actual value, the percent difference is calculated as (2009 -2008)/2008. If the actual value is greater than the model value, the percent difference iscalculated as (2008 - 2009)/2009.
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Variation in “Typical” Alameda County Pedestrian Activity Pattern
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95% of mid-day counts are between 20%above and 20% below the hourly mean
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Variation in Pedestrian Volumes
• Time of day, weather, etc. (accounted for)• Measurement error• “Unexplainable” variation
– Individual sickness, people walking for scenery, store sales, etc.– Not feasible to predict in a planning-level model– Require additional data and cost for small benefit
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Alameda County Revised ModelEstimated Weekly Pedestrian Crossings =
0.987 * Total population within 0.5-miles of theintersection
+ 2.19 * Total employment within 0.25-miles of theintersection
+ 71.1 * Number of commercial properties within 0.25-miles of the intersection
+49,300 * Number of regional transit stations within 0.10-miles of the intersection
- 4850 (Constant)
Adjusted R2 = 0.900Root Mean Squared Error = 5310Explanatory variables significant at 93% confidence interval
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Key Consideration for Applying ExistingPedestrian & Bicycle Volume Models
• Designed for estimating volumes at neighborhood,corridor, and community levels. Actual pedestriancounts should be used for site-level safety, design,and engineering analyses.
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Schneider, R.J., et al. “Development and Application of the San Francisco Pedestrian Intersection Volume Model” (2012).Map prepared by Fehr & Peers Transportation Consultants
Application for Pedestrian Safety Analysis:San Francisco Pedestrian Volume Model
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Schneider, R.J., et al. “Development and Application of the San Francisco Pedestrian Intersection Volume Model” (2012)
San Francisco Pedestrian Volume Model
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Reported pedestrian crashes
Schneider, R.J., et al. “Development and Application of the San Francisco Pedestrian Intersection Volume Model” (2012).Map prepared by Fehr & Peers Transportation Consultants
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Model-estimated pedestrian crossings
Schneider, R.J., et al. “Development and Application of the San Francisco Pedestrian Intersection Volume Model” (2012).Map prepared by Fehr & Peers Transportation Consultants
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Highest Estimated Pedestrian Crash Risk
Schneider, R.J., et al. “Development and Application of the San Francisco Pedestrian Intersection Volume Model” (2012).Map prepared by Fehr & Peers Transportation Consultants
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General Characteristics of Intersectionswith Highest Pedestrian Risk in SF
• Most were unsignalized intersections.• Many were along multilane arterial roadways.• Several were located near schools.• Several were in areas with steep slopes.
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Bicycle Intersection Volume Models
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San Diego County Bicycle Volume ModelPM Peak Hour Intersection Volume =
BAM = -4.279 + 0.718 * C + 0.438 * ED
Where:BAM = Morning peak bicycle countC = Footage of Class I bicycle path within a quarter-mileED = Employment density within a quarter-mile
R2 = 0.474Explanatory variables significant at 95% confidence interval
Source: Jones, M.G., S. Ryan, J. Donlan, L. Ledbetter, L. Arnold, and D. Ragland. Seamless Travel:Measuring Bicycle and Pedestrian Activity in San Diego County and its Relationship to Land Use,Transportation, Safety, and Facility Type, Prepared by Alta Planning & Design and UC BerkeleySafeTREC, California Department of Transportation Task Order 6117, 2010.
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San Diego County Bicycle Volume Model
Source: Jones, M.G. et al. Seamless Travel: Measuring Bicycle and Pedestrian Activity in San DiegoCounty and its Relationship to Land Use, Transportation, Safety, and Facility Type, 2010.
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Santa Monica Bicycle Volume ModelPM Peak Hour Bicycle Intersection Volume =
+ 10.97 * Land Use Mix+ 0.342 * PM Bus Frequency– 5.809 x 10-3 * Population Density Under Age 18+ 5.581 * Bike Network Score+ 14.89 (Constant)
R2 = 0.471Explanatory variables significant at 95% confidence interval
Haynes, M. and S. Andrzejewski. “Santa Monica Bicycle & Pedestrian Demand Analysis,” Presentation byFehr & Peers Transportation Consultants, April 20, 2010
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Alameda County Bicycle Volume Models
Source: Griswold, J.B., A. Medury, and R.J. Schneider. “Pilot Models for Estimating Bicycle IntersectionVolumes,” Transportation Research Record, Transportation Research Board, 2011.
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Alameda County Bicycle Volume Models
Source: Griswold, J.B., A. Medury, and R.J. Schneider. “Pilot Models for Estimating Bicycle IntersectionVolumes,” Transportation Research Record, Transportation Research Board, 2011.
• Commercial properties within 0.1 miles• Bicycle facility on intersection approach• Distance to UC Berkeley• Slope• Roadway network connectivity
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Common Bicycle Volume Model Variables
• Presence of bicycle facilities (e.g., multi-use trails,bicycle lanes)
• Employment or population density• Proximity to commercial areas
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Future Research
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Conclusions• Volume model uses: Planning, general risk analysis• Location-based models have been developed recently
– Simple regression equations with spreadsheet applications– Other methods are being explored (Portland, NCHRP, others)
• Community-specific models (No universal model yet)• Planning-level accuracy• Pedestrian models more common than bicycle
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Questions & Discussion
UC Berkeley Safe Transportation Research & Education Center(SafeTREC)
www.safetrec.berkeley.edu
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Thank You!
Archive at http://www.walkinginfo.org/webinars Downloadable and streaming recording,
transcript, presentation slidesQuestions? E-mail David Ragland at [email protected] E-mail John Bigham at [email protected] E-mail Robert Schneider at