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The Aggregate The Aggregate Rail Ridership Rail Ridership
Forecasting Forecasting Model: OverviewModel: Overview
Dave Schmitt, AICPDave Schmitt, AICP
Southeast Florida Users GroupSoutheast Florida Users GroupNovember 14November 14thth 2008 2008
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What is It?What is It?
A sketch-planning tool consisting of CTPP A sketch-planning tool consisting of CTPP 2000 data, GIS info, programs, control 2000 data, GIS info, programs, control files, and a spreadsheet collectively used to files, and a spreadsheet collectively used to develop an estimate of the ridership develop an estimate of the ridership potential for a new rail systempotential for a new rail system
Based on 20 recently-built light and Based on 20 recently-built light and commuter rail projectscommuter rail projects
Two spreadsheets: light rail and commuter Two spreadsheets: light rail and commuter rail; all other materials are identicalrail; all other materials are identical
Sponsored by FTA; developed by AECOMSponsored by FTA; developed by AECOM
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CTPP 2000 DataCTPP 2000 DataPart 1 – Workers at home-endPart 1 – Workers at home-end
Part 2 – Workers at work-endPart 2 – Workers at work-end
Part 3 – Flows Part 3 – Flows
CTPP1INC_TZ.exe,CTPP1INC_TZ.exe,
CTPP1INC_BG.exe, CTPP1INC_BG.exe, andand
CTPP1INC_TR.exe CTPP1INC_TR.exe programsprograms
Calculates proportion of households in Calculates proportion of households in low, medium and high income low, medium and high income categories by geographic unitcategories by geographic unit
CTPP2EMP_TZ.exe,CTPP2EMP_TZ.exe,
CTPP2EMP_BG.exe, CTPP2EMP_BG.exe, andand
CTPP2EMP_TR.exe CTPP2EMP_TR.exe programsprograms
Calculates workers in each geographic Calculates workers in each geographic unit and estimates employment densityunit and estimates employment density
CTPP3.exeCTPP3.exe program program Helps to extract tract-level data from Helps to extract tract-level data from region- or state-wide filesregion- or state-wide files
GIS infoGIS infoRail station points;Rail station points;
Proportion of tracts/zones within range Proportion of tracts/zones within range of stationsof stations
RailMarket.exeRailMarket.exe program program
Calculates the number of workers who Calculates the number of workers who both live and work within particular both live and work within particular distances of a rail station by income distances of a rail station by income group and employment density categorygroup and employment density category
SpreadsheetSpreadsheetRecords service variables and Records service variables and RailMarketRailMarket results; produces ridership results; produces ridership potential estimatepotential estimate
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LRT Model EquationLRT Model Equation
Total Weekday Unlinked Rail Trips =Total Weekday Unlinked Rail Trips =
Weekday Unlinked Drive Access to Work Rail Trips + Weekday Unlinked Drive Access to Work Rail Trips +
Weekday Unlinked Other Rail TripsWeekday Unlinked Other Rail Trips
Weekday Unlinked Drive Access to Work Rail Trips =Weekday Unlinked Drive Access to Work Rail Trips =
0.030 * CTPP PNR 6 -to-1 Mile JTW Flows (<50K Den) +0.030 * CTPP PNR 6 -to-1 Mile JTW Flows (<50K Den) +
0.202 * CTPP PNR 6 -to-1 Mile JTW Flows (>50K Den)0.202 * CTPP PNR 6 -to-1 Mile JTW Flows (>50K Den)
Weekday Unlinked Other (Non-Drive Access to Work) Rail Trips =Weekday Unlinked Other (Non-Drive Access to Work) Rail Trips =0.395 * CTPP 2 -to-1 Mile JTW Flows (<50K Den) +0.395 * CTPP 2 -to-1 Mile JTW Flows (<50K Den) +
0.445 * CTPP 2 -to-1 Mile JTW Flows (>50K Den)0.445 * CTPP 2 -to-1 Mile JTW Flows (>50K Den)
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CR Model EquationCR Model EquationCommuter Rail Weekday Unlinked Trips = Commuter Rail Weekday Unlinked Trips =
Nominal Ridership x Demand Adjustment FactorNominal Ridership x Demand Adjustment Factor
Nominal Ridership = Nominal Ridership =
0.069*High Income CTPP PNR 6-to-1 JTW flows + 0.069*High Income CTPP PNR 6-to-1 JTW flows +
0.041*Medium Income CTPP PNR 6-to-1 JTW flows + 0.041*Medium Income CTPP PNR 6-to-1 JTW flows +
0.151*Low Income CTPP 2-to-1 JTW flows0.151*Low Income CTPP 2-to-1 JTW flows
Demand Adjustment Factor=Demand Adjustment Factor= (1+0.3*Percent Deviation in (1+0.3*Percent Deviation in Average System Speed) xAverage System Speed) x
(1+0.3*Percent Deviation in Train Miles per Mile) (1+0.3*Percent Deviation in Train Miles per Mile) x x
Rail Connection IndexRail Connection Index
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CR Model Equation (2)CR Model Equation (2)Percent Deviation in Average System Speed=Percent Deviation in Average System Speed=
System Average Speed-35.7 mph / [ System Average System Average Speed-35.7 mph / [ System Average Speed+35.7)/2]Speed+35.7)/2]
System Average Speed=System Average Speed=
Annual Revenue Vehicle Miles/Annual Revenue Vehicle Annual Revenue Vehicle Miles/Annual Revenue Vehicle HoursHours
Percent Deviation in Train Miles per Mile=Percent Deviation in Train Miles per Mile=
Weekday Train Miles per Directional Route Mile-10.3 / Weekday Train Miles per Directional Route Mile-10.3 /
[(Weekday Train Miles per Directional Route Mile+10.3)/2][(Weekday Train Miles per Directional Route Mile+10.3)/2]
Weekday Train Miles per Directional Route Mile=Weekday Train Miles per Directional Route Mile=
Annual Revenue Vehicle Miles/250/Average Train LengthAnnual Revenue Vehicle Miles/250/Average Train Length
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ApplicationsApplications
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Applications – City AApplications – City A New rail line between CBD and New rail line between CBD and
suburban activity centers; strong suburban activity centers; strong corridor bus ridership & servicecorridor bus ridership & service
Compared ARRF LRT model with travel Compared ARRF LRT model with travel demand model resultsdemand model results
ResultsResults ARRF LRT model results were 100% higher ARRF LRT model results were 100% higher
than travel demand model estimatesthan travel demand model estimates Stronger motivation to investigate transit Stronger motivation to investigate transit
model parameters; subsequently identified model parameters; subsequently identified issues with walk- and auto-access issues with walk- and auto-access connector methodologyconnector methodology
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Applications – City A Applications – City A (cont’d)(cont’d)
ConclusionsConclusions ARRF model may partially explain ARRF model may partially explain
attractiveness of rail over existing attractiveness of rail over existing bus servicebus service
TDM path-builder probably better TDM path-builder probably better at evaluating bus/rail competition:at evaluating bus/rail competition: Equal service levels for bus & railEqual service levels for bus & rail Buses are just as close or closer to Buses are just as close or closer to
corridor activity centerscorridor activity centers
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Applications – City BApplications – City B
New rail line between CBD and New rail line between CBD and suburban residential areassuburban residential areas
Used ARRF to develop rationale Used ARRF to develop rationale for alternative-specific constant for alternative-specific constant
Results on next slide…Results on next slide…
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Ridership Forecasts – City BRidership Forecasts – City B
WalkWalk Drive/ Drive/ Drop-OffDrop-Off TotalTotal
ARRFARRF 14,79414,794 6,5486,548 21,34221,342
TDM ModelTDM Model
(no bias)(no bias)11,52011,520 4,5564,556 16,07616,076
TDM ModelTDM Model
(7.5 minute walk, 15 (7.5 minute walk, 15 minute drive)minute drive)
13,14513,145 6,3416,341 19,48719,487
TDM ModelTDM Model
(10 minute walk, 15 (10 minute walk, 15 minute drive)minute drive)
14,77014,770 6,2776,277 21,04721,047
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Applications – City CApplications – City C Streetcar in low density urban Streetcar in low density urban
activity center; existing service activity center; existing service is local & primarily captive is local & primarily captive marketmarket
ARRF LRT model compared with ARRF LRT model compared with travel demand model (2000 trip travel demand model (2000 trip tables, 2030 networks)tables, 2030 networks)
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Applications – City C Applications – City C (cont’d)(cont’d)
ResultResult Aggregate model forecast 120% higher Aggregate model forecast 120% higher
than travel demand modelthan travel demand model
ConclusionConclusion ARRF model may partially explain ARRF model may partially explain
attractiveness of rail over existing service, attractiveness of rail over existing service, but does not well-represent benefits of but does not well-represent benefits of project since:project since:
The project mode is different than calibrated The project mode is different than calibrated modemode
Lack of choice market not consistent with LRT Lack of choice market not consistent with LRT sample citiessample cities
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Applications – City DApplications – City D Commuter rail between two Commuter rail between two
adjacent metropolitan areas; adjacent metropolitan areas; some express bus service to each some express bus service to each CBD, but no service between CBD, but no service between CBD’sCBD’s
Commuter rail ARRF model Commuter rail ARRF model compared with travel demand compared with travel demand model (2000 trip tables, 2030 model (2000 trip tables, 2030 networks) applied to networks) applied to eacheach CBD CBD
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Applications – City D Applications – City D (cont’d)(cont’d)
ResultResult Aggregate model forecast 130% higher Aggregate model forecast 130% higher
than travel demand modelthan travel demand model
ConclusionConclusion ARRF model may partially explain ARRF model may partially explain
attractiveness of rail over existing attractiveness of rail over existing commuter bus service, but does not commuter bus service, but does not well-represent benefits of project since well-represent benefits of project since lack of service between CBDs unlike CR lack of service between CBDs unlike CR sample citiessample cities
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Applications – City EApplications – City E New commuter rail line to high New commuter rail line to high
mode share CBD with established mode share CBD with established “choice market” commuter bus “choice market” commuter bus service from large park and ride service from large park and ride facilitiesfacilities
Commuter rail ARRF model Commuter rail ARRF model compared with travel demand model compared with travel demand model (2000 trip tables, 2030 networks) (2000 trip tables, 2030 networks) appliedapplied
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Applications – City E Applications – City E (cont’d)(cont’d)
ResultResult Aggregate model forecast 30% Aggregate model forecast 30%
lower than travel demand modellower than travel demand model
ConclusionConclusion Existing commuter (“choice”) Existing commuter (“choice”)
market in corridor stronger than market in corridor stronger than CR sample citiesCR sample cities
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ProcessProcess
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General ProcedureGeneral Procedure1.1. Obtain basic input filesObtain basic input files
2.2. Determine the socio-economic Determine the socio-economic characteristics of the geographycharacteristics of the geography
3.3. Prepare the CTPP Part 3 flow dataPrepare the CTPP Part 3 flow data
4.4. Determine the relationships between rail Determine the relationships between rail stations & geographystations & geography
5.5. Run Run RailMarketRailMarket program to determine the program to determine the number of work for both live & work number of work for both live & work nearby rail stationsnearby rail stations
6.6. Enter the information from Enter the information from RailMarketRailMarket into the model spreadsheetinto the model spreadsheet
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Station Buffers Station Buffers
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SpreadsheetsSpreadsheetsProject:Alternative:Date:
Input Data
1. System Operational Characteristics 1a. Annual Revenue Vehicle Miles 1b. Annual Revenue Vehicle Hours 1c. Average Consist Length 1d. Weighted Operating Days per Year 1e. Directional Route Miles 1f. Rail Connection Index (1 if connects to urban rail distributor to CBD, else .5)
2. CTPP Flows 2a. Home within 2 miles of any station and Work within 1 mile of any station 2.a.i Low Income
2b. Home within 6 miles of a PNR station and Work within 1 mile of any station 2.b.i Medium Income 2.b.ii High Income
Parameters
1. Calibration Average system speed 35.700 2. Demand elasticity with respect to speed 0.300 3. Calibration Average Weekday Train Miles per Directional Route Mile 10.300 4. Demand elasticity with respect to Train Miles per Directional Route Mile 0.300
5. Unlinked Other (non-Drive Access to Work) low income/CTPP Flow 0.151 6. Unlinked Drive Access to Work medium income rail trips/CTPP Flow 0.041 7. Unlinked Drive Access to Work high income rail trips/CTPP Flow 0.069
Demand Adjustment Factor
Computed Speed 0.0Adjustment for Speed 0.40 Computed Weekday Train Miles Per Dir. Rte Mile 0.0Adjustment for Train Miles Per Directional Route Mile 0.40 Adjustment for Rail Connection - Total Demand Adjustment Factor -
Commuter Rail Unlinked Trips
Nominal Daily Unlinked Other (non-Drive Access to Work) low density rail trips - Nominal Daily Unlinked Drive Access to Work low density rail trips - Nominal Daily Unlinked Drive Access to Work high density rail trips -
Subtotal Nominal Daily rail trips - Demand Adjustment Factor - Total Daily Unlinked Commuter Rail Trips -
Project:
Alternative:
Date:
Input Data
1. Rail Line Directional Route Miles 68.8
2. CTPP Flows 2a. Home within 2 miles of any station and Work within 1 mile of any station 2.a.i Destination has <50,000 work trip ends per square mile 33,523 2.a.ii Destination has >50,000 work trip ends per square mile 16,292
Total (check) 49,815 2b. Home within 6 miles of a PNR station and Work within 1 mile of any station 2.b.i Destination has <50,000 work trip ends per square mile 69,298 2.b.ii Destination has >50,000 work trip ends per square mile 40,057
Total(check) 109,355
Parameters
1. Unlinked trips per mile 772.000 2. Unlinked Other (non-Drive Access to Work) low density rail trips/CTPP Flow 0.395 3. Unlinked Other (non-Drive Access to Work) high density rail trips/CTPP Flow 0.449 4. Unlinked Drive Access to Work low density rail trips/CTPP Flow 0.030 5. Unlinked Drive Access to Work high density rail trips/CTPP Flow 0.202
Distance-Based Model
Daily Unlinked Rail Trips 53,114
CTPP-Based Model
Daily Unlinked Other (non-Drive Access to Work) low density rail trips 13,242 Daily Unlinked Other (non-Drive Access to Work) high density rail trips 7,315
Subtotal Daily Unlinked Other (non-Drive Access to Work) rail trips 20,557
Daily Unlinked Drive Access to Work low density rail trips 2,079 Daily Unlinked Drive Access to Work high density rail trips 8,092
Subtotal Daily Unlinked Drive Access to Work rail trips 10,170
Total Daily Unlinked rail trips 30,727
St Louis LRT
Year 2000 Calibration Run
1/25/2006
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Materials Available Materials Available from FTAfrom FTA
Detailed documentationDetailed documentation Part-1: Model Application GuidePart-1: Model Application Guide Part-2: Input Data Development Part-2: Input Data Development
GuideGuide Part-3: Model Calibration ReportPart-3: Model Calibration Report
CTPP CTPP and and RailMarketRailMarket programs programs Spreadsheets: LRT and CRSpreadsheets: LRT and CR Contact: Contact: [email protected]@dot.gov
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Thank you!Thank you!