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Evaluating Robustness of Signal Timings for Conditions of Varying Traffic Flows. 2013 Mid-Continent Transportation Research Symposium – August 16, 2013 – 9:30AM – 12:00PM Cameron Kergaye , PhD, PE, PMP Director of Research Utah Department of Transportation. Traffic Signal Optimization. - PowerPoint PPT Presentation
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Evaluating Robustness of Signal Timings for Conditions of Varying Traffic Flows2013 Mid-Continent Transportation Research Symposium – August 16, 2013 – 9:30AM – 12:00PM
Cameron Kergaye, PhD, PE, PMPDirector of ResearchUtah Department of Transportation
Traffic Signal Optimization
Should signal timings be optimized for high-than-average traffic counts?
How should signal timing optimization accommodate multiple counts?
Summary
Signal timing plans perform best based on average traffic flows mean, mode, and median when exposed to day-to-day traffic flow variability
Optimizing signal timings for higher traffic demand is better than for lower traffic demand Should be used only when sufficient traffic data are
unavailable.
Introduction Optimization of signal timings is considered to be one
of the most effective tools to improve traffic operations on urban arterials.
However, once traffic signal systems are retimed and implemented, quality of their performance largely depends on day-to-day variability of traffic flows in the field.
As soon as traffic patterns change significantly, performance of the signal timings deteriorates.
Current signal timing practice recommends development of separate signal timing plans for major day-to-day traffic patterns (weekday, weekend, special events, etc.).
Introduction When adaptive traffic control is implemented it is
impractical to develop plans for every traffic pattern that warrants a separate signal timing plan.
Therefore, it is important to develop signal timing plans that will minimize disbenefits of implementing signal timing plans in variable traffic conditions.
Research Background Signal timing plans are based on traffic data that are
usually collected during a short term effort (e.g. 1-week).
The data includes 24-hour weekly volume profiles, turning movement counts, vehicular speeds, and travel time runs.
The data is analyzed with other sources to ensure that they are representative of common field conditions.
Research Background
What is a representative traffic volume pattern? It is the one that generates signal timings that work
best in a variety of traffic conditions.
Finding such a traffic volume pattern and optimizing signal timings in field experiments requires significant resources. Therefore, we use traffic simulation and other methods
that do not require field experiments.
Research Contribution Weekday PM-Peak hour traffic flows from the field are
modeled in microsimulation for a year. Two factors made this modeling approach possible:
Comprehensive set of field traffic flows collected during an entire year
Special tool to validate and balance traffic flows for the model.
Signal timing plans are optimized for each of the representative traffic flows resembling the process that usually occurs in practice.
Each of the signal timing plans is evaluated for the entire set of traffic flows to determine the best representative set of traffic flows.
Study Area
Park City, UT
14 Intersections
Long Corridor and Small Business District
N
0 0.5 1 km
Validation Results – Southbound
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1 2 3 4 5 6 7 8 9 10 11 12 13Intersection Segments
Trav
el T
ime
(sec
)
2007 Field Microsimulation
Validation Results – Northbound
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Intersection Segments
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ime
(sec
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2007 Field Microsimulation
MethodologyAccurately model day-to-day traffic variations in microsimulation Collect and Process Field Traffic Volumes
Traffic Volumes Recorded by SCATSTraffic Volumes Collected by Automatic Traffic RecordersManually Collected Traffic Volumes
Verify SCATS Traffic Volumes Build, Calibrate, and Validate the VISSIM Model Model Variability of Traffic Flows in VISSIM
Prepare for Modeling Variability of Traffic Flows in MicrosimulationVerify the reasonableness of SCATS traffic volumesBalance traffic flows in the networkVerify VISSIM Traffic Flows
Develop signal timing plans based on traffic flows of representative days Select scenarios of ‘representative-day traffic volumes’ Optimize signal timings in VISGAOST Evaluate Optimized Signal Timings in VISSIM
Scats Output with Traffic Volumes
B) Volume Store (VS) Output
A) Strategic Monitor (SM) Output
Variation of Traffic Flows
Thanksgiving Holiday 2009
Thanksgiving Holiday 2006
Christmas 2009
Memorial Day 2007
Memorial Day 2009
Martin Luther King Day 2009
Christmas 2006
Mean = 1185
St. Dev. = 40.74
Mean = 1135
St. Dev. = 249.49
Balancing Traffic Flows
Peak-Hour ATR & Scats Data
A) ATR 605 Soutbound
D) ATR 606 NorthboundC) ATR 606 Soutbound
B) ATR 605 Northbound
100
200
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700
800Tr
affic V
olum
e (v
eh/h
our)
Days
SB Field SB SCATS
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1400
Traffi
c Vol
ume
(veh
/hou
r)
Days
NB Field NB SCATS
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Traffi
c Vol
ume
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SB Field SB SCATS Data
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Traffi
c Vol
ume
(veh
/hou
r)
Days
NB Field NB SCATS
Verifying Reasonableness of Scats Traffic Volumes
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14001 5 9 13 17 21 25 29 33 37 41 45 49 53 57 61 65 69 73 77 81 85 89 93 97 101
105
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Traffi
c Vol
umes
(veh
/hou
r)
Turning Movements (in Ascending Order based on Hourly Traffic Flows)
2005 Manually Counted Traffic Volumes 2009 Average SCATS Traffic Volumes
2009 Minimum SCATS Traffic Volumes 2009 Maximum SCATS Traffic Volumes
Verifying Match of Scats & Vissim Traffic Flowsy = 0.949x + 9.1946
R² = 0.9474
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Aver
age
VISS
IM Tu
rnin
g M
ovem
ents
Cou
nts [
veh/
hour
]
Average Field Turning Movements Counts [veh/hour]
Optimizing Signal Timings In Visgaost
Split[1,8]=[[10.0,23.0,10.0,23.0,10.0,23.0,10.0,23.0]];LeadPhase[1,8]=[[1,0,0,1,1,0,1,0]];CycleLength[1]=[66.0];Offset[1]=[30.0];
VISSIM InputSignalGroups[8]=[1.0,2.0,3.0,4.0,5.
0,6.0,7.0,8.0];
Simulation time: 600 to 4200Parameter ValueTotal travel time[h] 835.8Total delay time[h] 159.2Number of stops 21828Stopped delay[h] 84.2
Network Performance
VISSIM Output
VISSIM VISGAOST
Signal Timings
PerformanceMeasures
“Representative Days” of Traffic Volumes
• AVERAGE• MAX• MEDIAN• MIN• MODE• 75th PERCENTILE• 85th PERCENTILE
Reduction of PI During Visgaost Optimizations
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Perfo
rman
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rman
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dex
-All
othe
rs
Number of Generations
MIN AVERAGE MODE MEDIAN 75th PERCENTILE 85th PERCENTILE MAX
Cycle Lengths & Offsets
Cycle Lengths, Offsets & Splits
Variations in Performance Indices
4500
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Net
wor
k Tr
affic F
low
[veh
/hou
r]
Perf
orm
ance
Inde
x
DatesMAX MIN EXISTING
AVERAGE MODE 85th PERCENTILE
75th PERCENTILE MEDIAN Total Network Traffic Flow
Performances Based on Various ‘Representative-Days’
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wor
k Tr
affic T
hrou
ghpu
t [ve
h/ho
ur]
Perf
orm
ance
Inde
x
Optimization Scenarios
Performance Index Traffic Demand
ConclusionsSignal timings optimized for median traffic flows were best. Similar results were found for other average traffic flows (i.e. mean and mode).
Findings show that signal timings developed for traffic flows that most frequently occur in the field bring more benefits than those that are developed for less frequent but higher traffic flows.
Basing signal timings on higher-than-average traffic demand still generates better results than those developed for lower traffic flows.
This is justified where there is a shortage of reliable traffic flow data from the field and when demand is expected to grow significantly.