Respuesta :
Part A:
Given that Y is the number of phone calls received in a day and that a new iPhone user receives an average of 4.2 phone calls per hour.
Thus, the average number of phone calls received in a day is 4.2 * 24 = 100.8
Therefore, the λ for Y is 100.8
Part B:
The standard deviation of a Poisson distribution is given by
[tex]\sigma=\sqrt{\lambda}[/tex]
Thus, the standard deviation of X is given by
[tex]\sigma=\sqrt{4.2}=2.05[/tex]
Therefore, the standard deviation of X is 2.05.
Part C:
The standard deviation of Y is given by
[tex]\sigma=\sqrt{100.8}=10.04[/tex]
Therefore, the standard deviation of X is 10.04.
Part D:
The probability of a Poisson distribution is given by
[tex]P(X=x)=e^{-\lambda} \frac{\lambda^x}{x!} [/tex]
where, x is the number of occurence of the event in the given period.
Thus, the probability that no calls are received in an hour is given by
[tex]P(X=0)=e^{-4.2} \frac{(4.2)^0}{0!} =0.015[/tex]
Therefore, the probability that no calls are received in an hour is 0.015
Part E:
We approximate the Poisson distribution using Normal distribution by noting that for a Poisson distribution
[tex]\mu=\lambda \\ \\ \sigma^2=\lambda \\ \\ \sigma=\sqrt{\lambda}[/tex]
The probability of a normal distribution is given by
[tex]P(X\ \textless \ x)=P\left(z\ \textless \ \frac{x-\mu}{\sigma} \right)[/tex]
Thus, the probability that more than 120 calls are received in a day is given by
[tex]P(X\ \textgreater \ 120)=1-P(X\leq120) \\ \\ =1-P\left(z\leq \frac{120-100.8}{10.04} \right)=1-P(z\leq1.912) \\ \\ =1-0.97208=0.0279[/tex]
Therefore, the probability that more than 120 calls are received in a day is 0.0279
Part F:
We also approximate this using Normal distribution
The probability of a normal distribution between two value (a, b) is given by
[tex]P(a\ \textless \ X\ \textless \ b)=P\left(z\ \textless \ \frac{b-\mu}{\sigma} \right)-P\left(z\ \textless \ \frac{a-\mu}{\sigma} \right)[/tex]
Thus, the probability that Y is between 90 and 110 inclusive is given by
[tex]P(90\leq X\leq 110)=P\left(z\leq \ \frac{110-100.8}{10.04} \right)-P\left(z\leq \frac{90-100.8}{10.04} \right) \\ \\ =P(z\leq0.916)-P(-1.076)=0.82025-0.14103=0.67922[/tex]
Therefore, the probability that Y is between 90 and 110 is 0.67922
Part G:
The variance of aY is given by
[tex]Var(aY)=a^2Var(Y)[/tex]
Thus, the variance of [tex] \sqrt{2} Y[/tex] is given by
[tex]Var( \sqrt{2} Y)=( \sqrt{2} )^2Var(Y)=2(100.8)=201.6[/tex]
Therefore, the variance of [tex] \sqrt{2} Y[/tex] is 201.6
Part H:
We approximate this using Normal distribution
The probability of a normal distribution is given by
[tex]P(X\ \textless \ x)=P\left(z\ \textless \ \frac{x-\mu}{\sigma} \right)[/tex]
Thus, the probability that 120 or fewer calls are received in a day is given by
[tex]P(X\leq120)=P\left(z\leq \frac{120-100.8}{10.04} \right) \\ \\ =P(z\leq1.912)=0.97208[/tex]
Since, this distribution holds for all hours and days and one call is independent from another. Assuming that there are seven days in a week.
The probability that 120 or fewer calls are received for every day of this week is given by
[tex](0.97208)^7=0.8202[/tex]
Therefore, the probability that 120 or fewer calls are received for every day of this week is 0.8202
Given that Y is the number of phone calls received in a day and that a new iPhone user receives an average of 4.2 phone calls per hour.
Thus, the average number of phone calls received in a day is 4.2 * 24 = 100.8
Therefore, the λ for Y is 100.8
Part B:
The standard deviation of a Poisson distribution is given by
[tex]\sigma=\sqrt{\lambda}[/tex]
Thus, the standard deviation of X is given by
[tex]\sigma=\sqrt{4.2}=2.05[/tex]
Therefore, the standard deviation of X is 2.05.
Part C:
The standard deviation of Y is given by
[tex]\sigma=\sqrt{100.8}=10.04[/tex]
Therefore, the standard deviation of X is 10.04.
Part D:
The probability of a Poisson distribution is given by
[tex]P(X=x)=e^{-\lambda} \frac{\lambda^x}{x!} [/tex]
where, x is the number of occurence of the event in the given period.
Thus, the probability that no calls are received in an hour is given by
[tex]P(X=0)=e^{-4.2} \frac{(4.2)^0}{0!} =0.015[/tex]
Therefore, the probability that no calls are received in an hour is 0.015
Part E:
We approximate the Poisson distribution using Normal distribution by noting that for a Poisson distribution
[tex]\mu=\lambda \\ \\ \sigma^2=\lambda \\ \\ \sigma=\sqrt{\lambda}[/tex]
The probability of a normal distribution is given by
[tex]P(X\ \textless \ x)=P\left(z\ \textless \ \frac{x-\mu}{\sigma} \right)[/tex]
Thus, the probability that more than 120 calls are received in a day is given by
[tex]P(X\ \textgreater \ 120)=1-P(X\leq120) \\ \\ =1-P\left(z\leq \frac{120-100.8}{10.04} \right)=1-P(z\leq1.912) \\ \\ =1-0.97208=0.0279[/tex]
Therefore, the probability that more than 120 calls are received in a day is 0.0279
Part F:
We also approximate this using Normal distribution
The probability of a normal distribution between two value (a, b) is given by
[tex]P(a\ \textless \ X\ \textless \ b)=P\left(z\ \textless \ \frac{b-\mu}{\sigma} \right)-P\left(z\ \textless \ \frac{a-\mu}{\sigma} \right)[/tex]
Thus, the probability that Y is between 90 and 110 inclusive is given by
[tex]P(90\leq X\leq 110)=P\left(z\leq \ \frac{110-100.8}{10.04} \right)-P\left(z\leq \frac{90-100.8}{10.04} \right) \\ \\ =P(z\leq0.916)-P(-1.076)=0.82025-0.14103=0.67922[/tex]
Therefore, the probability that Y is between 90 and 110 is 0.67922
Part G:
The variance of aY is given by
[tex]Var(aY)=a^2Var(Y)[/tex]
Thus, the variance of [tex] \sqrt{2} Y[/tex] is given by
[tex]Var( \sqrt{2} Y)=( \sqrt{2} )^2Var(Y)=2(100.8)=201.6[/tex]
Therefore, the variance of [tex] \sqrt{2} Y[/tex] is 201.6
Part H:
We approximate this using Normal distribution
The probability of a normal distribution is given by
[tex]P(X\ \textless \ x)=P\left(z\ \textless \ \frac{x-\mu}{\sigma} \right)[/tex]
Thus, the probability that 120 or fewer calls are received in a day is given by
[tex]P(X\leq120)=P\left(z\leq \frac{120-100.8}{10.04} \right) \\ \\ =P(z\leq1.912)=0.97208[/tex]
Since, this distribution holds for all hours and days and one call is independent from another. Assuming that there are seven days in a week.
The probability that 120 or fewer calls are received for every day of this week is given by
[tex](0.97208)^7=0.8202[/tex]
Therefore, the probability that 120 or fewer calls are received for every day of this week is 0.8202
