The critical flow ratios for a three-phase signal are found to be 0.30, 0.25, and 0.25. The total time lost in the cycle is 10 s. Pedestrian crossings at this junction are not significant. The respective Green times (expressed in seconds and rounded off to the nearest integer) for the three phases are

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GATE CE 2016 Official Paper: Shift 2

Option 1 : 34, 28, and 28

CT 3: Building Materials

2962

10 Questions
20 Marks
12 Mins

__Concept:__

**Webster’s method for an optimum cycle time of a signal is given by**

\({C_o} = \frac{{1.5L + 5}}{{1 - Y}}\)

**Effective green time on i ^{th }lane**

\({G_i} = \frac{{{Y_i}}}{Y} \times \left( {{C_o} - L} \right)\)

L = lost time per cycle

Y = Sum of the ratios of normal to saturated flows

__Calculation:__

Given,

Y = y_{1} + y_{2} + y_{3}

Y= 0.30 + 0.25 + 0.25 = 0.80

L = 10 sec (given)

∴ Optimum cycle time

\(\begin{array}{l} {C_0} = \frac{{1.5L + 5}}{{1 - Y}}\\ {C_0} = \frac{{\left( {1.5 \times 10} \right) + 5}}{{1 - 0.80}} = \frac{{15 + 5}}{{0.20}} = \frac{{20}}{{0.2}} = 100\;sec \end{array}\)

Now green times are calculated by,

\({G_1} = \frac{{{y_1}}}{y}\left( {{C_0} - L} \right) = \frac{{0.30}}{{0.80}}\left( {100 - 10} \right)\) = 33.75 ≈ 34 sec

\({G_2} = \frac{{{y_2}}}{y}\left( {{C_0} - L} \right) = \frac{{0.25}}{{0.80}}\left( {100 - 10} \right)\) = 28.11 ≈ 28 sec

\({G_3} = \frac{{{y_3}}}{y}\left( {{C_0} - L} \right) = \frac{{0.28}}{{0.80}}\left( {100 - 10} \right)\) = 28.11 ≈ 28 sec