Question
Phonics is an instructional method in which children are taught to connect sounds with letters or groups of letters. A sample of 136 first-graders who were learning English were asked to identify as many letter sounds as possible in a period of one minute. The average number of letter sounds identified was 34.1 with a standard deviation of 23.32
(a) Construct a 99.8% confidence interval for the mean number of letter sounds identified in one minute. Round the answers to at least two decimal places..
(a) Construct a 99.8% confidence interval for the mean number of letter sounds identified in one minute. Round the answers to at least two decimal places..
Answers
GPT-4o mini
To construct a 99.8% confidence interval for the mean number of letter sounds identified, we can use the following formula for the confidence interval:
\[
CI = \bar{x} \pm z \left( \frac{s}{\sqrt{n}} \right)
\]
Where:
- \(\bar{x}\) is the sample mean
- \(z\) is the z-value that corresponds to the desired confidence level
- \(s\) is the sample standard deviation
- \(n\) is the sample size
Given the values:
- Sample size, \(n = 136\)
- Sample mean, \(\bar{x} = 34.1\)
- Sample standard deviation, \(s = 23.32\)
First, we need to find the z-value for a 99.8% confidence level. We can find this using a z-table or calculator. The critical value for a 99.8% confidence level is approximately \(z \approx 2.666\).
Next, we can calculate the standard error (SE):
\[
SE = \frac{s}{\sqrt{n}} = \frac{23.32}{\sqrt{136}} \approx \frac{23.32}{11.662} \approx 2.00
\]
Now we can calculate the margin of error (ME):
\[
ME = z \cdot SE = 2.666 \cdot 2.00 \approx 5.332
\]
Finally, we can construct the confidence interval:
\[
CI = \bar{x} \pm ME = 34.1 \pm 5.332
\]
Calculating the lower and upper limits:
\[
\text{Lower limit} = 34.1 - 5.332 \approx 28.77
\]
\[
\text{Upper limit} = 34.1 + 5.332 \approx 39.43
\]
Thus, the 99.8% confidence interval for the mean number of letter sounds identified in one minute is approximately:
\[
\boxed{(28.77, 39.43)}
\]
\[
CI = \bar{x} \pm z \left( \frac{s}{\sqrt{n}} \right)
\]
Where:
- \(\bar{x}\) is the sample mean
- \(z\) is the z-value that corresponds to the desired confidence level
- \(s\) is the sample standard deviation
- \(n\) is the sample size
Given the values:
- Sample size, \(n = 136\)
- Sample mean, \(\bar{x} = 34.1\)
- Sample standard deviation, \(s = 23.32\)
First, we need to find the z-value for a 99.8% confidence level. We can find this using a z-table or calculator. The critical value for a 99.8% confidence level is approximately \(z \approx 2.666\).
Next, we can calculate the standard error (SE):
\[
SE = \frac{s}{\sqrt{n}} = \frac{23.32}{\sqrt{136}} \approx \frac{23.32}{11.662} \approx 2.00
\]
Now we can calculate the margin of error (ME):
\[
ME = z \cdot SE = 2.666 \cdot 2.00 \approx 5.332
\]
Finally, we can construct the confidence interval:
\[
CI = \bar{x} \pm ME = 34.1 \pm 5.332
\]
Calculating the lower and upper limits:
\[
\text{Lower limit} = 34.1 - 5.332 \approx 28.77
\]
\[
\text{Upper limit} = 34.1 + 5.332 \approx 39.43
\]
Thus, the 99.8% confidence interval for the mean number of letter sounds identified in one minute is approximately:
\[
\boxed{(28.77, 39.43)}
\]
Incorrect. its 27.80 < u < 40.40
Now if an 80% confidence interval were constructed with these data, would it be wider or narrower than the interval constructed in Part (a)?
Now if an 80% confidence interval were constructed with these data, would it be wider or narrower than the interval constructed in Part (a)?
GPT-4o mini
I apologize for the earlier miscalculation of the confidence interval. Let's clarify how the width of confidence intervals varies with different confidence levels:
When constructing confidence intervals, the width is determined by the critical value (z-score) associated with the desired confidence level. Higher confidence levels result in wider intervals, and lower confidence levels produce narrower intervals.
Given:
- The original confidence interval was calculated at a 99.8% confidence level, which has a higher z-score (approximately 2.666).
- An 80% confidence interval will have a lower confidence level and therefore a smaller critical z-score.
For an 80% confidence level, the critical z-score is approximately \(1.28\).
### Conclusion:
Since the critical value (z-score) for the 80% confidence interval is smaller than the critical value for the 99.8% confidence interval, the width of the 80% confidence interval will be **narrower** than the width of the 99.8% confidence interval.
Thus, the answer to your question is that the 80% confidence interval would be **narrower** than the interval constructed in Part (a).
When constructing confidence intervals, the width is determined by the critical value (z-score) associated with the desired confidence level. Higher confidence levels result in wider intervals, and lower confidence levels produce narrower intervals.
Given:
- The original confidence interval was calculated at a 99.8% confidence level, which has a higher z-score (approximately 2.666).
- An 80% confidence interval will have a lower confidence level and therefore a smaller critical z-score.
For an 80% confidence level, the critical z-score is approximately \(1.28\).
### Conclusion:
Since the critical value (z-score) for the 80% confidence interval is smaller than the critical value for the 99.8% confidence interval, the width of the 80% confidence interval will be **narrower** than the width of the 99.8% confidence interval.
Thus, the answer to your question is that the 80% confidence interval would be **narrower** than the interval constructed in Part (a).