Respuesta :
Answer:
[tex]S^2_p =\frac{(13-1)(5)^2 +(10 -1)(3)^2}{13 +10 -2}=18.143[/tex]
And the deviation would be just the square root of the variance:
[tex]S_p=4.259[/tex]
Then the statistic is given by:
[tex]t=\frac{(12 -9)-(0)}{4.259\sqrt{\frac{1}{13}+\frac{1}{10}}}=1.674[/tex]
And the correct option would be:
t = 1.674
Step-by-step explanation:
Data given:
[tex]n_1 =13[/tex] represent the sample size for group 1
[tex]n_2 =10[/tex] represent the sample size for group 2
[tex]\bar X_1 =12[/tex] represent the sample mean for the group 1
[tex]\bar X_2 =9[/tex] represent the sample mean for the group 2
[tex]s_1=5[/tex] represent the sample standard deviation for group 1
[tex]s_2=3[/tex] represent the sample standard deviation for group 2
We are assuming two independent samples from two normal distributions with equal variances we are assuming that
[tex]\sigma^2_1 =\sigma^2_2 =\sigma^2[/tex]
And the statistic is given by this formula:
[tex]t=\frac{(\bar X_1 -\bar X_2)-(\mu_{1}-\mu_2)}{S_p\sqrt{\frac{1}{n_1}+\frac{1}{n_2}}}[/tex]
Where t follows a t distribution with [tex]n_1+n_2 -2[/tex] degrees of freedom and the pooled variance [tex]S^2_p[/tex] is given by this formula:
[tex]\S^2_p =\frac{(n_1-1)S^2_1 +(n_2 -1)S^2_2}{n_1 +n_2 -2}[/tex]
The system of hypothesis on this case are:
Null hypothesis: [tex]\mu_1 \leq \mu_2[/tex]
Alternative hypothesis: [tex]\mu_1 > \mu_2[/tex]
The pooled variance is given by:
[tex]S^2_p =\frac{(13-1)(5)^2 +(10 -1)(3)^2}{13 +10 -2}=18.143[/tex]
And the deviation would be just the square root of the variance:
[tex]S_p=4.259[/tex]
Then the statistic is given by:
[tex]t=\frac{(12 -9)-(0)}{4.259\sqrt{\frac{1}{13}+\frac{1}{10}}}=1.674[/tex]
And the correct option would be:
t = 1.674
