Answer:
(0.6613, 8.3387)
Step-by-step explanation:
Let the heights of men be the first population and the heights of women be the second population. Then
We have [tex]n_{1} = 15[/tex], [tex]\bar{x}_{1} = 69.4[/tex], [tex]s_{1} = 3.09[/tex] and
[tex]n_{2} = 7[/tex], [tex]\bar{x}_{2} = 64.9[/tex], [tex]s_{2} = 2.58[/tex]. The pooled
estimate is given by
[tex]s_{p}^{2} = \frac{(n_{1}-1)s_{1}^{2}+(n_{2}-1)s_{2}^{2}}{n_{1}+n_{2}-2} = \frac{(15-1)(3.09)^{2}+(7-1)(2.58)^{2}}{15+7-2} = 8.68[/tex]
The 99% confidence interval for the true mean difference between the mean height of the men and the mean height of the women is given by (if the samples are independent)
[tex](\bar{x}_{1}-\bar{x}_{2})\pm t_{0.01/2}s_{p}\sqrt{\frac{1}{15}+\frac{1}{7}}[/tex], i.e.,
[tex](69.4-64.9)\pm t_{0.005}2.946\sqrt{\frac{1}{15}+\frac{1}{7}}[/tex]
where [tex]t_{0.005}[/tex] is the 0.5th quantile of the t distribution with (15+7-2) = 20 degrees of freedom. So
[tex]4.5\pm(-2.845)(2.946)(0.458)[/tex], i.e.,
(0.6613, 8.3387)
