Answer:
Step-by-step explanation:
From the information given:
the rate of the cars = [tex]\dfrac{1}{5} \ car / min = 0.2 \ car /min[/tex]
the rate of the buses = [tex]\dfrac{1}{10} \ bus / min = 0.1 \ bus /min[/tex]
the rate of motorcycle = [tex]\dfrac{1}{30} \ motorcycle / min = 0.0333 \ motorcycle /min[/tex]
The probability of any event at a given time t can be expressed as:
[tex]P(event \ (x) \ in \ time \ (t)\ min) = \dfrac{e^{-rate \times t}\times (rate \times t)^x}{x!}[/tex]
∴
(a)
[tex]P(2 \ car \ in \ 20 \ min) = \dfrac{e^{-0.20\times 20}\times (0.2 \times 20)^2}{2!}[/tex]
[tex]P(2 \ car \ in \ 20 \ min) =0.1465[/tex]
[tex]P ( 1 \ motorcycle \ in \ 20 \ min) = \dfrac{e^{-0.0333\times 20}\times (0.0333 \times 20)^1}{1!}[/tex]
[tex]P ( 1 \ motorcycle \ in \ 20 \ min) = 0.3422[/tex]
[tex]P ( 0 \ buses \ in \ 20 \ min) = \dfrac{e^{-0.1\times 20}\times (0.1 \times 20)^0}{0!}[/tex]
[tex]P ( 0 \ buses \ in \ 20 \ min) = 0.1353[/tex]
Thus;
P(exactly 2 cars, 1 motorcycle in 20 minutes) = 0.1465 × 0.3422 × 0.1353
P(exactly 2 cars, 1 motorcycle in 20 minutes) = 0.0068
(b)
the rate of the total vehicles = 0.2 + 0.1 + 0.0333 = 0.3333
the rate of vehicles with exact change = rate of total vehicles × P(exact change)
[tex]= 0.3333 \times \dfrac{1}{4}[/tex]
= 0.0833
∴
[tex]P(zero \ exact \ change \ in \ 10 minutes) = \dfrac{e^{-0.0833\times 10}\times (0.0833 \times 10)^0}{0!}[/tex]
P(zero exact change in 10 minutes) = 0.4347
c)
The probability of the 7th motorcycle after the arrival of the third motorcycle is:
[tex]P( 4 \ motorcyles \ in \ 45 \ minutes) =\dfrac{e^{-0.0333\times 45}\times (0.0333 \times 45)^4}{4!}[/tex]
[tex]P( 4 \ motorcyles \ in \ 45 \ minutes) =0.0469[/tex]
Thus; the probability of the 7th motorcycle after the arrival of the third one is = 0.0469
d)
P(at least one other vehicle arrives between 3rd and 4th car arrival)
= 1 - P(no other vehicle arrives between 3rd and 4th car arrival)
The 3rd car arrives at 15 minutes
The 4th car arrives at 20 minutes
The interval between the two = 5 minutes
For Bus:
P(no other vehicle other vehicle arrives within 5 minutes is)
= [tex]\dfrac{6}{12} = 0.5[/tex]
For motorcycle:
[tex]= \dfrac{2 }{12} = \dfrac{1 }{6}[/tex]
∴
The required probability = [tex]1 - \Bigg ( \dfrac{e^{-0.5 \times 0.5^0}}{0!} \times \dfrac{e^{-1/6}\times (1/6)^0}{0!} \Bigg)[/tex]
= 1- 0.5134
= 0.4866
