Respuesta :
Answer:
a) [tex] df = n-1= 20-1=19[/tex]
For this case the value of [tex]\alpha=0.1[/tex] , since is a right tailed test we need a critical value on the t distribution with 19 degrees of freedom that accumulates 0.1 of the area on the right and we got:
[tex] t_{cric}= 1.328[/tex]
b) [tex] df = n-1= 10-1=9[/tex]
For this case the value of [tex]\alpha=0.05[/tex] , since is a left tailed test we need a critical value on the t distribution with 9 degrees of freedom that accumulates 0.05 of the area on the right and we got:
[tex] t_{cric}=-1.833 [/tex]
c) [tex] df = n-1= 11-1=10[/tex]
For this case the value of [tex]\alpha=0.01[/tex] and [tex]\alpha/2=0.005[/tex] , since is a two tailed tailed test we need a critical value on the t distribution with 10 degrees of freedom that accumulates 0.005 of the area on both tails and we got:
[tex] t_{cric}=\pm 3.169[/tex]
Step-by-step explanation:
Previous concepts
The t distribution (Student’s t-distribution) is a "probability distribution that is used to estimate population parameters when the sample size is small (n<30) or when the population variance is unknown".
The shape of the t distribution is determined by its degrees of freedom and when the degrees of freedom increase the t distirbution becomes a normal distribution approximately.
The degrees of freedom represent "the number of independent observations in a set of data. For example if we estimate a mean score from a single sample, the number of independent observations would be equal to the sample size minus one."
Solution to the problem
Part a
We can calculate the degrees of freedom first:
[tex] df = n-1= 20-1=19[/tex]
For this case the value of [tex]\alpha=0.1[/tex] , since is a right tailed test we need a critical value on the t distribution with 19 degrees of freedom that accumulates 0.1 of the area on the right and we got:
[tex] t_{cric}= 1.328[/tex]
Part b
We can calculate the degrees of freedom first:
[tex] df = n-1= 10-1=9[/tex]
For this case the value of [tex]\alpha=0.05[/tex] , since is a left tailed test we need a critical value on the t distribution with 9 degrees of freedom that accumulates 0.05 of the area on the right and we got:
[tex] t_{cric}=-1.833 [/tex]
Part c
We can calculate the degrees of freedom first:
[tex] df = n-1= 11-1=10[/tex]
For this case the value of [tex]\alpha=0.01[/tex] and [tex]\alpha/2=0.005[/tex] , since is a two tailed tailed test we need a critical value on the t distribution with 10 degrees of freedom that accumulates 0.005 of the area on both tails and we got:
[tex] t_{cric}=\pm 3.169[/tex]
