QUESTION IMAGE
Question
what i have learned
activity 2
a. find the values for each of the following degree of freedom and t - values with the given percentile. write your answer on the space provided.
- $t_{\alpha/2}$ and $n = 16$ for the 99% confidence interval
$df = $ ____ $t_{(0.005,15)} = $ ____
- $t_{\alpha/2}$ and $n = 25$ for the 98% confidence interval
$df = $ ____ $t_{(0.01,24)} = $ ____
- $t_{\alpha/2}$ and $n = 8$ for the 95% confidence interval
$df = $ ____ $t_{(0.025,7)} = $ ____
- $t_{\alpha/2}$ and $n = 12$ for the 90% confidence interval
$df = $ ____ $t_{(0.05,11)} = $ ____
- $t_{\alpha/2}$ and $n = 20$ for the 99% confidence interval
$df = $ ____ $t_{(0.005,19)} = $ ____
b. summarize the lesson by completing the sentences below:
- when asked of an estimation of population mean but population standard deviation is unknown, the ______ can be used.
- the t - distribution is similar to the standard normal distribution in the following ways:
2.1 ______
2.2 ______
2.3 ______
2.4 ______
Part A: Finding t - values and Degrees of Freedom
1. \( t_{\alpha/2} \) and \( n = 16 \) for 99% confidence interval
Step 1: Calculate degrees of freedom (\( df \))
The formula for degrees of freedom for a t - distribution when dealing with a sample mean is \( df=n - 1 \). Given \( n = 16 \), we have \( df=16 - 1=15 \).
Step 2: Determine the significance level (\( \alpha \)) and \( \alpha/2 \)
For a 99% confidence interval, the confidence level \( CL = 0.99 \). The significance level \( \alpha=1 - CL=1 - 0.99 = 0.01 \). Then \( \alpha/2=\frac{0.01}{2}=0.005 \).
Step 3: Find the t - value \( t_{\alpha/2,df} \)
We need to find \( t_{0.005,15} \). Using a t - distribution table or a statistical software, \( t_{0.005,15}\approx2.947 \).
2. \( t_{\alpha/2} \) and \( n = 25 \) for 98% confidence interval
Step 1: Calculate degrees of freedom (\( df \))
Using \( df=n - 1 \) with \( n = 25 \), we get \( df=25 - 1 = 24 \).
Step 2: Determine the significance level (\( \alpha \)) and \( \alpha/2 \)
For a 98% confidence interval, \( CL = 0.98 \), so \( \alpha=1 - 0.98=0.02 \). Then \( \alpha/2=\frac{0.02}{2}=0.01 \).
Step 3: Find the t - value \( t_{\alpha/2,df} \)
We need to find \( t_{0.01,24} \). Using a t - distribution table or software, \( t_{0.01,24}\approx2.492 \).
3. \( t_{\alpha/2} \) and \( n = 8 \) for 95% confidence interval
Step 1: Calculate degrees of freedom (\( df \))
Using \( df=n - 1 \) with \( n = 8 \), we get \( df=8 - 1 = 7 \).
Step 2: Determine the significance level (\( \alpha \)) and \( \alpha/2 \)
For a 95% confidence interval, \( CL = 0.95 \), so \( \alpha=1 - 0.95 = 0.05 \). Then \( \alpha/2=\frac{0.05}{2}=0.025 \).
Step 3: Find the t - value \( t_{\alpha/2,df} \)
We need to find \( t_{0.025,7} \). Using a t - distribution table or software, \( t_{0.025,7}\approx2.365 \).
4. \( t_{\alpha/2} \) and \( n = 12 \) for 90% confidence interval
Step 1: Calculate degrees of freedom (\( df \))
Using \( df=n - 1 \) with \( n = 12 \), we get \( df=12 - 1 = 11 \).
Step 2: Determine the significance level (\( \alpha \)) and \( \alpha/2 \)
For a 90% confidence interval, \( CL = 0.90 \), so \( \alpha=1 - 0.90 = 0.10 \). Then \( \alpha/2=\frac{0.10}{2}=0.05 \).
Step 3: Find the t - value \( t_{\alpha/2,df} \)
We need to find \( t_{0.05,11} \). Using a t - distribution table or software, \( t_{0.05,11}\approx1.796 \).
5. \( t_{\alpha/2} \) and \( n = 20 \) for 99% confidence interval
Step 1: Calculate degrees of freedom (\( df \))
Using \( df=n - 1 \) with \( n = 20 \), we get \( df=20 - 1 = 19 \).
Step 2: Determine the significance level (\( \alpha \)) and \( \alpha/2 \)
For a 99% confidence interval, \( CL = 0.99 \), so \( \alpha=1 - 0.99 = 0.01 \). Then \( \alpha/2=\frac{0.01}{2}=0.005 \).
Step 3: Find the t - value \( t_{\alpha/2,df} \)
We need to find \( t_{0.005,19} \). Using a t - distribution table or software, \( t_{0.005,19}\approx2.861 \).
Part B: Summarizing the Lesson
- When asked for an estimation of the population mean but the population standard deviation is unknown, the t - distribution can be used.
- The t - distribution is similar to the standard normal distribution in the following ways:
2.1 Both are symmetric about the mean (the mean of both the t - distribution and the standard normal distribution is 0).
2.2 As the degrees of freedom of the t - distribution increase, the t - distribution approaches the standard normal distribution.
2.3 Both are bell - shaped curves.
2.4 The total area under both the t - distribution curve a…
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Part A: Finding t - values and Degrees of Freedom
1. \( t_{\alpha/2} \) and \( n = 16 \) for 99% confidence interval
Step 1: Calculate degrees of freedom (\( df \))
The formula for degrees of freedom for a t - distribution when dealing with a sample mean is \( df=n - 1 \). Given \( n = 16 \), we have \( df=16 - 1=15 \).
Step 2: Determine the significance level (\( \alpha \)) and \( \alpha/2 \)
For a 99% confidence interval, the confidence level \( CL = 0.99 \). The significance level \( \alpha=1 - CL=1 - 0.99 = 0.01 \). Then \( \alpha/2=\frac{0.01}{2}=0.005 \).
Step 3: Find the t - value \( t_{\alpha/2,df} \)
We need to find \( t_{0.005,15} \). Using a t - distribution table or a statistical software, \( t_{0.005,15}\approx2.947 \).
2. \( t_{\alpha/2} \) and \( n = 25 \) for 98% confidence interval
Step 1: Calculate degrees of freedom (\( df \))
Using \( df=n - 1 \) with \( n = 25 \), we get \( df=25 - 1 = 24 \).
Step 2: Determine the significance level (\( \alpha \)) and \( \alpha/2 \)
For a 98% confidence interval, \( CL = 0.98 \), so \( \alpha=1 - 0.98=0.02 \). Then \( \alpha/2=\frac{0.02}{2}=0.01 \).
Step 3: Find the t - value \( t_{\alpha/2,df} \)
We need to find \( t_{0.01,24} \). Using a t - distribution table or software, \( t_{0.01,24}\approx2.492 \).
3. \( t_{\alpha/2} \) and \( n = 8 \) for 95% confidence interval
Step 1: Calculate degrees of freedom (\( df \))
Using \( df=n - 1 \) with \( n = 8 \), we get \( df=8 - 1 = 7 \).
Step 2: Determine the significance level (\( \alpha \)) and \( \alpha/2 \)
For a 95% confidence interval, \( CL = 0.95 \), so \( \alpha=1 - 0.95 = 0.05 \). Then \( \alpha/2=\frac{0.05}{2}=0.025 \).
Step 3: Find the t - value \( t_{\alpha/2,df} \)
We need to find \( t_{0.025,7} \). Using a t - distribution table or software, \( t_{0.025,7}\approx2.365 \).
4. \( t_{\alpha/2} \) and \( n = 12 \) for 90% confidence interval
Step 1: Calculate degrees of freedom (\( df \))
Using \( df=n - 1 \) with \( n = 12 \), we get \( df=12 - 1 = 11 \).
Step 2: Determine the significance level (\( \alpha \)) and \( \alpha/2 \)
For a 90% confidence interval, \( CL = 0.90 \), so \( \alpha=1 - 0.90 = 0.10 \). Then \( \alpha/2=\frac{0.10}{2}=0.05 \).
Step 3: Find the t - value \( t_{\alpha/2,df} \)
We need to find \( t_{0.05,11} \). Using a t - distribution table or software, \( t_{0.05,11}\approx1.796 \).
5. \( t_{\alpha/2} \) and \( n = 20 \) for 99% confidence interval
Step 1: Calculate degrees of freedom (\( df \))
Using \( df=n - 1 \) with \( n = 20 \), we get \( df=20 - 1 = 19 \).
Step 2: Determine the significance level (\( \alpha \)) and \( \alpha/2 \)
For a 99% confidence interval, \( CL = 0.99 \), so \( \alpha=1 - 0.99 = 0.01 \). Then \( \alpha/2=\frac{0.01}{2}=0.005 \).
Step 3: Find the t - value \( t_{\alpha/2,df} \)
We need to find \( t_{0.005,19} \). Using a t - distribution table or software, \( t_{0.005,19}\approx2.861 \).
Part B: Summarizing the Lesson
- When asked for an estimation of the population mean but the population standard deviation is unknown, the t - distribution can be used.
- The t - distribution is similar to the standard normal distribution in the following ways:
2.1 Both are symmetric about the mean (the mean of both the t - distribution and the standard normal distribution is 0).
2.2 As the degrees of freedom of the t - distribution increase, the t - distribution approaches the standard normal distribution.
2.3 Both are bell - shaped curves.
2.4 The total area under both the t - distribution curve and the standard normal distribution curve is 1.
Final Answers for Part A
- \( df=\boldsymbol{15} \), \( t_{(0.005,15)}=\boldsymbol{2.947} \)
- \( df=\boldsymbol{24} \), \( t_{(0.01,24)}=\boldsymbol{2.492} \)
- \( df=\boldsymbol{7} \), \( t_{(0.025,7)}=\boldsymbol{2.365} \)
- \( df=\boldsymbol{11} \), \( t_{(0.05,11)}=\boldsymbol{1.796} \)
- \( df=\boldsymbol{19} \), \( t_{(0.005,19)}=\boldsymbol{2.861} \)
For Part B, the answers are as summarized above.