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Transportation Engineering

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Fundamentals of Traffic Signals Level of Service (LOS) The performance of a signalised intersection is measure considering the average stopped time delay. – PowerPoint PPT presentation

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Title: Transportation Engineering


1
Transportation Engineering
  • Fundamentals of Traffic Signals

2
Why Traffic Signals?
  • Conflicting traffic movements, make roadway
    intersections unsafe for vehicles and pedestrians
  • Intersections are a major source of crashes and
    vehicle delay (as vehicles yield to avoid
    conflicts with other vehicles).

3
Why Traffic Signals?
  • Most roadway intersections are not signalized due
    to low traffic volumes and adequate sight
    distances.
  • At some point, traffic volumes and crash
    frequency/severity (and other factors) reach a
    level that warrant the installation of traffic
    signals.
  • MUTCD def Any power-operated traffic control
    device other than a barricade warning light or
    steady burning electric lamp, by which traffic is
    warned or directed to take some specific action.
  • Manual on Uniform Traffic Control Devices (MUTCD)

4
Signalised Intersection
  • Two simple examples in Dublin

5
Signalised Intersection
6
Traffic Signals
7
History of Signalized Intersections
  • 1868 - London, UK
  • Manually operated semaphores (flags)
  • 1914 - Cleveland, OH
  • 1st Electric Signal
  • 1917 - Detroit, MI
  • Amber colour introduced

8
Traffic Signals Advantages
  • Ensures orderly movement of traffic in all
    directions
  • Provisions for the progressive flow of traffic in
    a signal-system corridor
  • Provisions for side-street vehicles to enter the
    traffic stream
  • Provisions for pedestrians to cross the street
    safely
  • Potential reduction of accidents, conflicts
    ensuring safety
  • Possible improvements in capacity, and
  • Possible reductions in delay

9
Traffic Signals Disadvantages
  • Large stop time delay
  • Complex signal design problems
  • The possible effects of a poorly-timed traffic
    signal
  • increase in vehicle delay,
  • increase vehicle crashes (particularly rear-end
    crashes)
  • disruption to traffic progression

10
Performance Measures
throughput
11
Terminology 1
  • Green time The time period in which the
  • traffic signal has the green indication
  • Red time The time period in which the
  • traffic signal has the red indication
  • Yellow time The time period in which the
  • traffic signal has the yellow indication
  • Cycle One complete rotation or sequence of
  • all signal indications
  • Cycle time (or cycle length) The total time
  • for the signal to complete one sequence of
  • signal indication.

12
Terminology 2
  • Permitted movement
  • A movement that is made through a conflicting
    pedestrian or other vehicle movement.
  • This is commonly used for right-turning
    movements where right-turn volumes are reasonable
    and where gaps in the conflicting movement are
    adequate to accommodate turns.
  • Protected movement
  • A movement that is made without conflict with
    other movements.
  • The movement is protected by traffic control
    signal design with a designated green time for
    the specific movement.

13
Terminology 3
  • Effective green time The effective green time,
    for a phase, is the time during which vehicles
    are actually discharging through the
    intersection.
  • Lost Time A portion of green or yellow time
    which is not utilised by traffic flow movements
    in a cycle.
  • Start-up lost time At the beginning of each
    green indication as the first few cars in a
    standing queue experience start-up delays. This
    delay is measured as start-up lost time.
  • The clearance lost time It is estimated by the
    amount of the yellow time not used by vehicles.

14
Traffic Signal Times
15
Basic Concepts of Intersection Signalisation
  • Discharge headways
  • Saturation flow at signalised intersections
  • Delay
  • Level of Service

16
Discharge Headways
  • Consider N vehicles discharging from the
    intersection when a green indication is received.
  • The first discharge headway is the time between
    the initiation of the green indication and the
    rear wheels of the first vehicle to cross over
    the stop line.
  • The Nth discharge headway (Ngt1) is the time
    between the rear wheels of the N-1th and Nth
    vehicles crossing over the stop line.

17
Discharge Headways
18
Discharge Headways
  • The headway begins to level off with 4 or 5th
    vehicle.
  • The level headway saturation headway

19
Saturation flow rate
  • In a given lane, if every vehicle consumes an
    average of h seconds of green time, and if the
    signal continues to be uninterruptedly green,
    then S vph could enter the intersection where S
    is the saturation flow rate (vehicles per hour of
    green time per lane) given by

20
Saturation Flow Rate
  • A variable directly related to discharge headway
  • In a given lane, if every vehicle consumes an
    average of h seconds of green time, and if the
    signal continues to be uninterruptedly green,
    then S vehicles per hour (vph) could enter the
    intersection where S is the saturation flow rate
    given by
  • In other words, s for a lane group/approach is
    the maximum number of vehicles from that lane
    group/approach that can pass through the
    intersection during one hour of continuous green
    time under the prevailing traffic and roadway
    conditions.

21
Saturation Flow Rate
  • The saturation flow rate is normally given in
    terms of straight-through passenger cars per hour
    of green.
  • Passenger Car Units A unit of measure whereby
    HOVs and turning movements are converted to
    straight-through passenger cars using
    multiplication factors. This allows to deal with
    mixed traffic streams more accurately than
    assuming that all vehicles are equal.
  • Unit for a single lane vphgpl (vehicles per hour
    of green time per lane) Here, vehicle is
    equivalent to passenger car units (pcu)
  • Unit for an approach vphg (vehicles per hour of
    green time) or pcuphg (passenger car units per
    hour of green time)

22
Factors Affecting Saturation Flow
  • Position of lane
  • Lane width
  • Approach grades
  • Parking conditions
  • Number of HOVs
  • Number of turning vehicles
  • Conflicting vehicular flow
  • Conflicting pedestrian flow
  • We will be only considering the geometric factors

23
Non-opposed Streams
  • For non-opposed streams saturation flow , s1 for
    individual lanes is given by,

24
Opposed Streams
25
Opposed Streams
26
Example 1
27
Example 2
28
Example 2
29
Capacity
  • The maximum hourly rate at which persons or
    vehicles can be reasonably expected to traverse a
    point or uniform segment of a lane or roadway
    during a given time period under prevailing
    traffic and roadway conditions.
  • (HCM 2000)
  • Unlike saturation flow, capacity considers
    traffic signal conditions
  • The formula for calculating capacity (c) is,
  • c (g/C) s N
  • Wherec capacity (pcu/hour)g Effective
    green time for the phase in question (sec)C
    Cycle length (sec)
  • N no. of laness Saturation flow rate
    (pcu/hour)

30
Capacity Calculation
  • Capacity can be calculated for two categories of
    flow uninterrupted and interrupted.
  • Uninterrupted-flow facilities
  • no fixed elements external to the traffic stream
    to interrupt flow
  • Motorways, multilane highway, dual carriageway
  • Interrupted-flow facilities
  • have controlled and uncontrolled access points
    that can interrupt flow
  • signalised and non-signalised intersections,
    urban streets

31
Delay
  • Very important performance measure for
    intersection signal design
  • A measure most directly related to Drivers
    experience
  • Stopped Time Delay time a vehicle stopped
    waiting to pass the intersection.
  • Approach Delay stopped time acceleration
    deceleration
  • Travel Time Delay (actual travel time-desired
    travel time)
  • Time-in-queue Delay Total time from joining a
    queue to passing the stop line
  • Delay is affected by cycle time, green time and
    volume to capacity ratio

32
Delay
  • Total delay
  • Stopped delay
  • Time in queue delay

33
Time-in-queue Delay
34
Level of Service (LOS)
  • The performance of a signalised intersection is
    measure considering the average stopped time
    delay.
  • The delay experienced by the average vehicle can
    be directly related to a level of service (LOS).
  • The LOS categories, contain information about the
    progression of traffic under the delay conditions
    that they represent.
  • The first step in the LOS analysis is to
    calculate the average delay per vehicle for
    various portions of the intersection. The LOS of
    can be calculated for an entire approach, or
    alternatively, for each individual lane.

35
Level of Service (Highways)
LOS A
LOS B
LOS C
LOS D
LOS E
LOS F
36
LOS
  • Level of Service A - Operations with low delay,
    or delays of less than 5.0 seconds per vehicle.
    This LOS is reached when most of the oncoming
    vehicles enter the signal during the green phase,
    and the driving conditions are ideal in all other
    respects as well.
  • Level of Service B - Operations with delays
    between 5.1 and 15.0 seconds per vehicle. This
    LOS implies good progression, with some vehicles
    arriving during the red phase.
  • Level of Service C - Operations with delays
    between 15.1 and 25.0 seconds per vehicle. This
    LOS witnesses longer cycle lengths and fair
    progression.

37
LOS
  • Level of Service D - Operations with delays
    between 25.1 and 40.0 seconds per vehicle. At
    this LOS, congestion is noticeable and longer
    delays may result from a combination of
    unfavorable progression, long cycle lengths, and
    high V/c ratios.
  • Level of Service E - Operations with delay
    between 40.1 and 60.0 seconds per vehicle. This
    LOS is considered unacceptable by most drivers.
    This occurs under over-saturated intersection
    conditions (V/c ratios over 1.0), and can also be
    attributed to long cycle lengths and poor
    progression.
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