Respuesta :
Answer:
a) [tex]\mu -3\sigma= 7.14 -3*0.7= 5.04[/tex]
[tex]\mu +3\sigma= 7.14 -3*0.7= 9.24[/tex]
b) [tex] z=\frac{7.8-7.14}{0.7}=0.943[/tex]
Using the normal approximation we can assume that this value 7.8 is approximately 1 deviation above the mean so then the percentage of values above is (100-68)/2 = 16%
c) [tex] z=\frac{5.7-7.14}{0.7}=-2.06[/tex]
[tex] z=\frac{9.2-7.14}{0.7}=2.94[/tex]
So we want to find approximately the % between 2 deviation below the mean and 3 deviation above the mean. For the % below two deviations from the mean we have (100-95)/2= 2.5% and for the % above 3 deviations from the mean we got (100-99.7)/2= 0.15% so then the percentage desired would be (100-2.5-0.15)% = 97.35%
Step-by-step explanation:
Let X the random variable that represent the times for the mile run of a population, and for this case we know the distribution for X is given by:
[tex]X \sim N(7.14,0.7)[/tex]
Where [tex]\mu=7.14[/tex] and [tex]\sigma=0.7[/tex]
We can use the z score to find how many deviation we are from the mean with this formula:
[tex]z=\frac{x-\mu}{\sigma}[/tex]
Part a
From the empirical rule we know that we have 99.7% of the data within 3 deviations from the mean and we can calculate the range like this:
[tex]\mu -3\sigma= 7.14 -3*0.7= 5.04[/tex]
[tex]\mu +3\sigma= 7.14 -3*0.7= 9.24[/tex]
Part b
We can use the z score and we got:
[tex] z=\frac{7.8-7.14}{0.7}=0.943[/tex]
Using the normal approximation we can assume that this value 7.8 is approximately 1 deviation above the mean so then the percentage of values above is (100-68)/2 = 16%
Part c
We can use the z score formula and we got:
[tex] z=\frac{5.7-7.14}{0.7}=-2.06[/tex]
[tex] z=\frac{9.2-7.14}{0.7}=2.94[/tex]
So we want to find approximately the % between 2 deviation below the mean and 3 deviation above the mean. For the % below two deviations from the mean we have (100-95)/2= 2.5% and for the % above 3 deviations from the mean we got (100-99.7)/2= 0.15% so then the percentage desired would be (100-2.5-0.15)% = 97.35%
