MindTap Engineering for Garber/Hoel's Traffic and Highway Engineering, 5th Edition, [Instant Access], 1 term (6 months)
MindTap Engineering for Garber/Hoel's Traffic and Highway Engineering, 5th Edition, [Instant Access], 1 term (6 months)
5th Edition
ISBN: 9781305581159
Author: Nicholas J. Garber; Lester A. Hoel
Publisher: Cengage Learning US
Question
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Chapter 8, Problem 18P
To determine

Effect on cycle length due to 20% higher pedestrian flow rates.

Expert Solution & Answer
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Answer to Problem 18P

Cycle length value increases with 4.76%, from 126 to 132.

Explanation of Solution

Given data:

MindTap Engineering for Garber/Hoel's Traffic and Highway Engineering, 5th Edition, [Instant Access], 1 term (6 months), Chapter 8, Problem 18P

Calculation:

Evaluating equivalent hourly flow −

  Equivalenthourlyflow=TrafficvolumePHF=1330.95140

Similarly, evaluating equivalent hourly flow for all traffic movements −

Table 1

Approach (width)N (56ft)S (56ft)E (68ft)W (68ft)
Left turn133/0.95 = 14073/0.95 = 77168/0.95 = 177134/0.95 = 142
Through movement443393593544
Right turn148143178188
Conflicting pedestrian volume94812641264948

Assuming lane configuration as one dedicated left turn and combined through and right lane −

Table 2

ApproachNSEW
Left14077177142
Through + Right589
(442+147)
535
(393+178)
771
(593+178)
730
(543+187)

Assume a phase scheme and find critical ratios( Yi ) and sum of critical ratios ( Yi ). Assuming phase as follows −

Table 3

-Phase lE-W (Left)Phase llE-W (Through)Phase lllN-S (Left)Phase lVN-S (Through)
qij177771140589
Sij10003000 (1600+1400)10003000 (1600+1400)
Yi= qijSij0.1770.2570.1400.196

Sum of critical ratios −

  Yi=Y1+Y2+Y3+........Yn=.177+0.257+0.140+0.196=0.77

Assuming lost time per phase ( li )= 3Sec

So, Total lost time −

  L=li=3+3+3+3=12Sec

Now, determining the optimum cycle length −

  Co=1.5L+51Yi=1.5×12+510.77=100Sec

(Cycle lengths are generally multiple of 5secor10sec, Hence OK)

Finding Total effective green time −

  Gie=CoL=10012=88Sec

Effective time for phase i can be calculated as −

  Gei=YiY1+Y2+Y3+........YnGie

For Phase l

  Gphasel=0.1770.177+0.257+0.140+0.196×88=20.23Sec

(Assuming yellow time as 4sec )

  (G+Y)phasel=20.23+4=24.23Sec25Sec

For Phase ll

  Gphasell=0.2570.177+0.257+0.140+0.196×88=29.37Sec

  (G+Y)phasell=29.37+4=33.37Sec34Sec

For Phase lll

  Gphaselll=0.1400.177+0.257+0.140+0.196×88=16Sec

  (G+Y)phaselll=16+4=20Sec

For Phase lV

  GphaselV=0.1960.177+0.257+0.140+0.196×88=22.4Sec

  (G+Y)phasel=22.4+4=26.4Sec27Sec

Table 4

Phase Allocated green & yellow time (in sec)
(G+Y)125
(G+Y)234
(G+Y)320
(G+Y)427

Total cycle length

  C=(G+Y)phasei+Totalredtimeinterval=(25+34+20+27)+4(1.5)=112Sec

Green time required for pedestrian crossing can be calculated as following formula:

(Assuming the crosswalk width as 9ft< 10ft ).

  Gp=3.2+LccSp+0.27Nped

Where,

  Lcc = cross walk length

  Sp = pedestrian speed (assuming as 4ftsec )

  Nped = number pedestrians crossing during an interval = vpedi3600C

  vpedi = pedestrian flow rate in the subject crossing for travel direction i( p/h)

  C = total cycle length

Calculating Nped for each direction:

  Nped for N direction = 9483600×112=29.4930sec

  Nped for S direction = 12643600×112=39.3240sec

  Nped for E direction = 12643600×112=39.3240sec

  Nped for W direction = 9483600×112=29.4930sec

Calculating minimum time required ( Gp ) for each approach:

Minimum time required for N approach ( GP1 ): 3.2+564+0.27×30=25.326sec

Minimum time required for S approach ( GP2 ): 3.2+564+0.27×40=28sec

Minimum time required for E approach ( GP3 ): 3.2+684+0.27×40=31sec

Minimum time required for W approach ( GP4 ): 3.2+684+0.27×30=28.329sec

Table 5

Phase Minimum green time (in sec)
GP126
GP228
GP331
GP429

  GP1 is greater than (G+Y)1 so the allocated green and yellow time for phase 1 is from the table 5 26 sec.

Sum of green and yellow time is given by,

  G1+G2+G3+G4=26sec+28sec+31sec+29sec=114sec

Total cycle length is given by,

  C=(totalgreenandyellowtime)+(totalredtime)C=(26+34+31+29)+(4×1.5)C=126sec

Now increasing the pedestrian volume with 20% and calculating the minimum time required by pedestrian for each approach:

  New pedestrian volume = old pedestrian volume + old pedestrian volume=948+948×20100=948+189.61138

Table 6

New conflicting pedestrian volume1138151715171138

According to the new pedestrian volume calculating minimum time required by pedestrian for each approach:

Calculating Nped for each direction:

  Nped for N direction = 11383600×126=39.8340sec

  Nped for S direction = 15173600×126=53.0954sec

  Nped for E direction = 15173600×126=53.0954sec

  Nped for W direction = 11383600×126=39.8340sec

Calculating new minimum time required ( Gp* ) for each approach:

Minimum time required for N approach ( GP1* )= 3.2+564+0.27×40=28sec

Minimum time required for S approach ( GP2* ) = 3.2+564+0.27×54=31.7832sec

Minimum time required for E approach ( GP3* ) = 3.2+684+0.27×54=34.78=35sec

Minimum time required for W approach ( GP4* ) = 3.2+684+0.27×40=31sec

Comparing the Gp* values with table 4, and selecting new values as shown in table below:

Selecting greater values in between both Gp* and (G+Y)i, which is taken as new minimum green time:

Table 7

Phase New minimum green time (in sec)
G1*28
G2*32
G3*35
G4*31

Sum of green and yellow time is given by,

  G1*+G2*+G3*+G4*=28sec+32sec+35sec+31sec=126sec

Total new cycle length is given by,

  C=(totalgreenandyellowtime)+(totalredtime)C=(28+32+35+31)+(4×1.5)C=132sec

Conclusion:

With using pedestrian volume flow rate 20% higher than given, cycle length increases by 4.76%.

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