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For each intersection analyzed the average control delay per vehicle per approach is determined for the <br />peak hour. A weighted average of control delay per vehicle is then determined for the intersection. A <br />LOS designation is given to the control delay to better describe the level of operation. A description of <br />levels of service for signalized intersections can be found in Table A-V <br />Table A-V: Description of Level of Service for Signalized Intersections <br />LOS Description <br /> Very low Control delay, up to 10 seconds per vehicle. Progression is extremely favorable, and most <br />A vehicles arrive during the green phase. Many vehicles do not stop at all. Shoff gcle lengths may tend to <br /> contribute to low delay values. <br />8 Control delay greater than 10 and up to 20 seconds per vehicle. There is good progression or short cycle <br /> lengths or both. More vehicles stop causing higher levels of delay. <br /> Control delay greater than 20 and up to 35 seconds per vehicle. Higher delays are caused by fair <br />C progression or longer cycle lengths or both. Individual Lytle failures may begin to appear. Cycle failure <br /> occurs when a given green phaze doe not serve queued vehicles, and overflow occurs. The number of <br /> vehicles stopping is significant, though many still pass through the intersection without stopping. <br /> Control delay greater than 35 and up to 55 seconds per vehicle. The influence of congestions becomes <br />D more noticeable. Longer delays may result from some combination of unfavorable progression, long cycle <br /> lengths, or high volumes. Many vehicles stop, the propottion of vehicles not stopping declines. Individual <br /> cycle failures are noticeable. <br /> Control delay greater than 55 and up to 80 seconds per vehicle. The limit of acceptable delay. High <br />E delays usually indicate poor progression, long cycle lengths, and high volumes. Individual gcle failures are <br /> frequent. <br /> Control delay in excess of 80 seconds per vehicle. Unacceptable to most drivers. Oversaturation, arrival <br />P flow rates exceed the capacity of the intersection. Many individual cycle failures. Poor progression and <br /> long cycle lengths may also be contributing factors to higher delay. <br />Source: Highway Capacity Manual 2000 <br />The use of control delay, which may also be referred to as signal delay, was introduced in the 1997 <br />update to the Highway Capacity Manual, and represents a departure from previous updates. In the third <br />edition, published in 1985 and the 1994 update to the third edition, delay only included stopped delay. <br />Thus, the LOS criteria listed in Table A-V differs from earlier criteria. <br />Unsignalized Intersections <br />The current procedures on unsignalized intersections were first introduced in the 1997 update to the <br />Highway Capacity Manual and represent a revision of the methodology published in the 1994 update to <br />the 1985 Highway Capacity Manual. The revised procedures use control delay as a measure of <br />effectiveness to determine LOS. Delay is a measure of driver discomfort, frustration, fuel consumption, <br />and increased travel time. The delay experienced by a motorist is made up of a number of factors that <br />relate to control, traffic and incidenu. Total delay is the difference between the travel time actually <br />experienced and the reference travel time that would result during base conditions, i, e., in the absence <br />of traffic control, geometric delay, any incidents, and any other vehicles. Control delay is the increased <br />time of travel for a vehicle approaching and passing through an unsignalized intersection, compared with <br />a free-Flow vehicle if it were not required to slow or stop at the intersection. <br />