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Chapter 7 Traffic Control and Analysis at Signalized Intersections

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Title: Chapter 7 Traffic Control and Analysis at Signalized Intersections


1
Chapter 7Traffic Control and Analysis at
Signalized Intersections
  • Principles of Highway Engineering and Traffic
    Analysis, 2005
  • Third Edition
  • Fred Mannering, Walter Kilareski
  • Scott Washburn

2
Basic Concepts
3
Signal Timing Terminology
  • Indication illumination of signal lenses which
    informs the driver as to which movements are
    permitted or prohibited
  • Cycle one complete rotation through all of the
    indications provided
  • Cycle length time required to complete one
    rotation, given in seconds, C
  • Yellow time the change interval, warns drivers
    that the signal is changing from green to red
  • Clearance interval the all red indication
  • Green time the go indication for a particular
    movement or set of movements
  • Red time the stop indication for a particular
    movement or set of movements
  • Phase a green interval plus the change interval
    and clearance intervals that follow it (typically
    related to a particular movement or approach)

4
Modes of Operation
  • Pretimed Operation preset cycle lengths and
    intervals. 3-dial signal controllers allow for
    three different cycles throughout the day.
  • Semi-Actuated detectors at minor approaches.
    Green for major street unless vehicle detected on
    minor street
  • Fully Actuated every approach has detectors.
    Green time allocated based on vehicle detection.
    Each cycle different, limits placed on min/max
    green times and min gaps between vehicles to
    maintain green indication.
  • Computer Controlled System wide control.
    Optimal progression patterns determined for
    system wide operation. In order to optimize,
    however, cycle lengths must be the same or
    multiples of a base to achieve optima performance.

5
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6
Inductive Loop
7
Machine-Vision Camera Detectors
8
Left Turn Timing
  • Permitted Left Turns drivers permitted to cross
    opposing traffic but must select their own gap
    (green ball on signal head)
  • Protected Left Turns left turns made without
    opposing through vehicular traffic (green arrow
    on signal head)
  • Protected/Permitted or Permitted/Protected left
    turns protected at the beginning of a phase, then
    permitted during through movement green time

9
Dual-Ring Configuration
  • Allows for maximum flexibility to control phase
    duration and sequencing of intervals
  • Best hardware to have when implementing
    fully-actuated signals
  • See Figure 7.3
  • Movements 1-4 can occur simultaneously with
    movements 5-8 (as long as the occur on the same
    side of the barrier)
  • The dual ring ability allows for skipping of
    phases where there isnt a need for them due to
    low flow
  • Allows the unused green to be allocated to more
    congested phases

10
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11
Discharge Headway
  • Discharge headway time passage between
    successive vehicles as they cross the curb line
    during a green phase. Measured at rear wheels of
    vehicles.
  • First headway longer than others. Includes
    driver reaction time, and acceleration time.
  • Second headway shorter, reaction and acceleration
    times overlap.
  • Eventually headways level out, typically around
    4-5 vehicle.
  • Once this occurs, saturation headway can be
    measured.

12
Saturation Flow Rate
  • Saturation headway hheadway achieved by stable
    moving platoon of vehicles passing through a
    green indication
  • Saturation Flow Rate every vehicle assumed to
    occupy h seconds of green time, and if signal
    always green, then s vehicles/hour could enter
    intersection
  • s 3600/h
  • If signal always green, could simply multiply by
    the number of lanes to estimate the capacity of
    the approach.
  • units of measure vehicles per hour of green
    time per lane, (vphgpl)

13
Lost Time
  • Time that is not effectively serving any movement
    or traffic
  • Total lost time includes start-up and clearance
    lost times
  • Start-up lost time signal indication turns from
    red to green and vehicles do not instantly move
    at the saturation flow rate
  • Clearance lost time later portion of the yellow
    phase all red phase

14
Start-up Lost Time
  • Need to account for the time lost when first few
    vehicles crossing intersection
  • Start-up lost time (l) actual
    headway-saturation headway multiplied by number
    of vehicles (n) traveling at headways greater
    than saturation headway (h)
  • Lost time also occurs when a movement is stopped
    (at the beginning of the clearance interval)

15
Total Lost Time
16
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17
Effective Green Time
  • Amount of time available to be used at a rate of
    one vehicle every h seconds
  • giGi Yi AR tL
  • gieffective green time
  • Giactual green time for movement i,sec
  • Yisum of yellow plus all red time for movement
    i,sec
  • tLtotal lost time per phase, sec
  • Total lost time includes start up time and
    clearance lost time (tLtsl tcl)

18
Green Ratio
  • Ratio of effective green time to cycle length for
    a particular movement
  • Simple capacity can be determined using
  • cisi(gi/C)
  • cicapacity of lanes serving movement i, vph
  • CSignal cycle length, sec
  • sisaturation flow rate for movement i, sec
  • gieffective green time for movement i,sec

19
Effective Red Time
  • Effective red time is the time in which the
    intersection is not being utilized by traffic

r effective red time for a traffic movement in
seconds R displayed red time for a traffic
movement in seconds tL total lost time for the
movement during a cycle in seconds
20
Simple Capacity Estimation
  • Approach or movement capacity can be estimated
    through a simple relationship

c capacity of a lane group or approach that are
served by a particular g s saturation
flow rate in veh/hr g/C ratio of the effective
green time to the total cycle length
21
Using Simple Queuing Models to Estimate Signal
Performance
  • Ex 7.1 in text
  • Pretimed signal with sat flow rate of 2400 vph
  • 24 sec of effective green time in 80 s cycle
  • Flow at approach is 500 vph
  • Estimate operational performance using D/D/1
    queuing.

22
Example Continued
  • Put arrival and departure rates in similar units

23
Example Continued
  • A variety of measures can be determined using
    equations 7.7-7.13

24
Estimating Delay at Real-World Signals
  • The D/D/1 models are limited by their assumption
    of uniform arrivals
  • For signals, non-uniform arrivals are much more
    likely than uniform arrivals
  • To determine LOS, control delay is estimated for
    traffic signals and unsignalized intersections
  • Control delay deceleration time, queue move-up
    time, stop time, and acceleration time through
    the intersection

25
HCM Delay Model
  • Total Average Individual Stopped Delay for Random
    Arrivals (sec/veh)

26
HCM Delay Model
  • daverage signal delay per vehicle in sec
  • d1avg delay per vehicle due to uniform arrivals
    in sec
  • PFprogression adjustment factor
  • d2avg delay per vehicle due to random arrivals
    in sec
  • d3avg delay per vehicle due to initial queue at
    start of analysis period in sec

27
HCM Delay Model
  • Ccycle length, sec
  • geffective green time for lane group in sec
  • Xv/c ratio for lane group
  • Tduration of analysis period in hours
  • kdelay adjustment factor that is dependent on
    signal controller mode
  • Iupstream filtering adjustment factors
  • clane group capacity in veh/hr

28
Example
  • An approach to a pretimed signalized intersection
    has
  • s 2400 veh/hr
  • 24 sec effective green
  • C 80 sec
  • Given flow 500 veh/hr no initial queue and
    flow accounts for 15-min period, determine
    average approach delay per cycle.

29
Example Continued
  • Calculate uniform delay first

30
Example Continued
  • Calculate Random Delay
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