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Lec 15, Ch.8, pp.291-304: Signal Timing (Objective)

Lec 15, Ch.8, pp.291-304: Signal Timing (Objective). Be able to state the objectives of signal timing Learn by heart signal-timing related terms (very important) Understand how the yellow interval is determined

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Lec 15, Ch.8, pp.291-304: Signal Timing (Objective)

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  1. Lec 15, Ch.8, pp.291-304: Signal Timing (Objective) • Be able to state the objectives of signal timing • Learn by heart signal-timing related terms (very important) • Understand how the yellow interval is determined • Know how to design signal timing for a fixed (pretimed) signal at an isolated intersection using the Webster’s model

  2. What we cover in class today… • Terms relating to signal timing • Objectives of signal timing • Concept behind the determination of yellow interval & dilemma zone • Determining cycle length for a pretimed, isolated signal using the Webster method • Allocating green time to each signal phase

  3. Terms relating to signal timing Cycle length Phase Interval Change interval All-red interval (clearance interval) Controller Phase B

  4. Terms relating to signal timing (cont) Offset All signal analyses are based on through passenger cars. This way the analyses became portable to any sites. Then you need conversion of other-than-passenger cars and other-than-through vehicles. Hence we need: Split phase Phase 1A Phase 1B Passenger car equivalent (PCE) Turning movement factors

  5. Terms relating to signal timing (cont) Peak-hour factor (PHF):A measure of the variability of demand during the peak hour. The smallest time period used for traffic analyses is 15 min. If PHF is known, Design hourly volume (DHV) is computed by DHV = (peak-hour volume)/PHF 412 390 380 375 Volume during peak hour PHF = 4 x Vol. During peak 15 min within peak hour 375 + 380 + 412 + 390 0.945 = = 4 x 412

  6. Terms relating to signal timing (cont) Lane Group: consisting of one or more lanes on an intersection approach and having the same green phase Critical Lane Group: the lane group that requires the longest green time in a phase. The critical lane group determines the green time that is allocated to that phase. Saturation flow rate: the flow rate in veh/hr that the lane group can carry if it has the green indication continuously (see eq. 8.3 for the formula used by the Highway Capacity Manual 2000.)

  7. Terms relating to signal timing (cont) Once you have adjusted for truck and turn movement factors, you are ready to design phasing. One hint: if the adjusted left turn passenger car equivalent volumes is greater than 120 vph, we usually need a left-turn phase, which means that we need a left-turn bay. Up to that value, the yellow interval can provide enough time for LTs. There are a few methods to deal with left-turns. In this class you need to know only the methods shown below (i.e. protected left-turn phases) and in Example 8-5. All others will be discussed in CE562. It is a complex issue. 130 600/2=300 140 576/2=288 A B C D Critical movement: The maximum volume (vph) in a phase.

  8. Objectives of signal timing • Reduce the average delay of all vehicles • Reduce the probability of accidents Minimize the possible conflict points by assigning the right of way to different traffic movements • Two conflicting objectives: • More phases, less conflict • More phases, more lost time • So, if at all possible, use: • 2 phases • Short cycle length

  9. Yellow interval & Dilemma zone X0: the min. distance from the intersection for which a vehicle traveling at the speed limit u0 during the yellow interval cannot go through the intersection without accelerating Distance traveled during yellow interval Where τmin: yellow interval Xc: the distance within which a vehicle traveling at the speed limit (u0) during the yellow interval cannot stop before encroaching on the intersection.

  10. Yellow interval & Dilemma zone (cont) For the dilemma zones to be eliminated, X0 = Xc: Comfortable deceleration rate: a = 0.27g Solve for the yellow interval: If the effect of grade is added: G = grade in decimals

  11. Cycle lengths of pretimed signals by the Webster Method Optimal cycle length C0 by the Webster method: L = Total lost time per cycle (sec), usually you lose 3 seconds per distinct phases. Yi = Max value of the ratios of approach flows (called “critical movement”) to saturation flows for all lane groups using phase i, qij/Sj  = Number of phases Vij = Flow on lane groups having the right of way during phase i Sj= Saturation flow on lane group j; for a through lane, about 1900 pcphgpl

  12. Cycle lengths of pretimed signals by the Webster Method (cont) Lost time for phase i: Total lost time: R = Total all-red during the cycle

  13. Usually li is about 3 seconds. Green time allocation Available total effective green time, Gte = C - L Distribute effective green to each phase i by: And the actual green time for each phase i is:

  14. Minimum green time At an intersection where a significant number of pedestrians cross, it is necessary to provide a minimum green time that will allow the pedestrians to safely cross the intersection. After allocating green time, you must check with the minimum green time for each phase. For WE > 10 ft For WE≤ 10 ft At an intersection where only a few pedestrians cross, this will be the length of green time for pedestrian actuated green.

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