Investigation 1.14: Teen Hearing Loss

Section 4.4 Investigation 1.14: Teen Hearing Loss

Shargorodsky, Curhan, Curhan, and Eavey (2010) examined hearing loss data for 1771 participants from the National Health and Nutrition Examination Survey (NHANES, 2005-6), aged 12–19 years. ("NHANES provides nationally representative cross-sectional data on the health status of the civilian, non-institutionalized U.S. population.") A standardized health exam was given along with the survey and through audiometric measurements, 333 teens were found to have at least some level of hearing loss (average hearing threshold level at least 15 dB in either ear).

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Image related to teen hearing loss study

News of this study spread quickly, many blaming the prevalence of hearing loss on the higher use of ear buds by teens. At MSNBC.com (8/17/2010), Carla Johnson summarized the study with the headline "1 in 5 U.S. teens has hearing loss, study says." We will first decide whether we consider this an appropriate headline. According to the 2008 U.S. Census, there were 21,469,780 teens in America between the ages of 15 and 19.

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Checkpoint 4.4.1. Define population.

Define the population of interest in this study in words.

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Hint.

The population is the group we want to generalize to.

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Solution.

All U.S. teens aged 12-19 years (or 15-19 per Census data)

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Checkpoint 4.4.2. Define parameter.

Define the parameter of interest in this study in words.

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Solution.

The proportion of all U.S. teens who have at least some level of hearing loss

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Checkpoint 4.4.3. Parameter symbol.

What symbol should we use for the parameter?

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\(N\)
\(n\)
\(\pi\)
\(\hat{p}\)
\(\bar{x}\)
\(\mu\)
\(\tilde{p}\)

Solution.

\(\pi\) = the proportion of all U.S. teens who have at least some level of hearing loss

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Checkpoint 4.4.4. State hypotheses.

State the null and alternative hypotheses for deciding whether these data provide convincing evidence against the headline "1 in 5 U.S. teens has hearing loss."

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\(H_0: \)

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\(H_a: \)

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Hint.

The headline claims "1 in 5" which is 0.20 or 20%. We’re testing whether the data provide evidence against this claim.

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Solution.

\(H_0: \pi = 0.20\) - The proportion of all U.S. teens with hearing loss is 0.20 (1 in 5).

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\(H_a: \pi \neq 0.20\) - The proportion of all U.S. teens with hearing loss is different from 0.20.

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Key Result: Central Limit Theorem for Sample Proportions (Expanded).

Combining what we have learned in the last few investigations, we can expand the Central Limit Theorem for a sample proportion: When drawing random samples from a large but finite population with a large enough sample size, then the sampling distribution of the sample proportion \(\hat{p}\) will be well modeled by a normal distribution with mean equal to \(\pi\text{,}\) the population proportion of successes, and standard deviation equal to \(SD(\hat{p}) = \sqrt{\frac{\pi(1-\pi)}{n}}\text{.}\)

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We consider the sample size large enough if \(n \times \pi > 10\) and \(n \times (1 - \pi) > 10\text{.}\)

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We consider the population size (\(N\)) large if it is more than 20 times the size of the sample.

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Checkpoint 4.4.5. Check technical conditions.

Assuming the null hypothesis is true, is the normal model appropriate for the distribution of sample proportions based on this sample size and on this population size? Justify your answers numerically.

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Sample size condition:

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Population size condition:

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Conclusion:

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Hint.

Check whether \(n \pi > 10\text{,}\) \(n(1-\pi) > 10\text{,}\) and \(N > 20n\text{.}\)

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Solution.

Sample size: \(1771 \times 0.20 = 354.2 > 10\) and \(1771 \times 0.80 = 1416.8 > 10\) ✓

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Population size: \(21,469,780 > 20 \times 1771 = 35,420\) ✓

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Yes, the normal model is appropriate because both conditions are met.

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Checkpoint 4.4.6. Carry out \(z\)-test.

Use technology (see Section 4.5) to carry out a \(z\)-test of the hypotheses you specified in checkpoint Checkpoint 4.4.4. Report the standardized statistic and p-value, and confirm how you would calculate the standardized statistic by hand.

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Sample proportion:

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Standardized statistic (\(z\)):

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p-value:

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Calculation by hand:

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Hint.

Use the Theory-Based Inference applet or calculate \(z = \frac{\hat{p} - \pi_0}{\sqrt{\frac{\pi_0(1-\pi_0)}{n}}}\)

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Solution.

\(\hat{p} = \frac{333}{1771} = 0.188\)

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\(z = \frac{0.188 - 0.20}{\sqrt{\frac{0.20(0.80)}{1771}}} = \frac{-0.012}{\sqrt{0.0000903}} = \frac{-0.012}{0.0095} \approx -1.26\)

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Two-sided p-value: 0.2068

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Checkpoint 4.4.7. Interpret test results.

Does this p-value provide convincing evidence (level of significance \(\alpha = 0.05\)) against the headline? Justify your answer (in context) and explain the reasoning behind your evidence or lack thereof.

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Hint.

Compare the p-value to 0.05. What does the p-value tell you about observing a sample proportion as extreme as 0.188?

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Solution.

No, this p-value (0.2068) is not small and does not provide convincing evidence against the claim that \(\pi = 0.20\text{.}\) We would get sample proportions as or more extreme as 0.188 (meaning at least as far from 0.20) in about 21% of random samples from a population where 20% of teens have some hearing loss. Therefore, the headline seems appropriate.

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Checkpoint 4.4.8. Calculate confidence interval.

Calculate and interpret a 95% confidence interval for the parameter (see Section 4.5). Is this interval consistent with your test decision? Explain.

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95% Confidence interval:

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Interpretation:

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Consistency with test:

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Hint.

Use the formula \(\hat{p} \pm z^* \sqrt{\frac{\hat{p}(1-\hat{p})}{n}}\) where \(z^* = 1.96\) for 95% confidence.

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Solution.

95% CI: (0.170, 0.206) or 17.0% to 20.6%

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We are 95% confident that between 17.0% and 20.6% of all U.S. teens have some form of hearing loss.

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Yes, this is consistent with the test decision because 0.20 is contained in the confidence interval, so it is a plausible value for \(\pi\text{.}\)

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Checkpoint 4.4.9. Evaluate generalizability.

Do you feel comfortable with generalizing the findings from your test and confidence interval to the population of all American teens in 2005-06? Explain.

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Hint.

Consider whether the sample was representative

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Solution.

Yes, we should feel comfortable generalizing because the NHANES claims to use nationally representative sampling methods, presumably using probability sampling.

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Study Conclusions.

We have no reason to doubt that the NHANES sample will be representative of the larger population of U.S. teens. Although we are not told how they selected the sample, they claim it was nationally representative, and presumably was collected using a probability sampling method. The population size (~21 million teens) is quite large compared to the sample size of nearly 1,800 teens, so that condition for using the normal model for the sampling distribution of the sample proportions is met. The sample size is also very large relative to the hypothesized population proportion of 0.20 (0.20 × 1771 = 354.2 and 0.80 × 1771 = 1416.8; both easily exceed 10). Therefore, calculations from the binomial probability model and the normal probability model will be quite similar. Under the null hypothesis that 20% of U.S. teens have some hearing loss, the sampling distribution of the sample proportion will be approximately normal, with a mean of 0.20 and a standard deviation of 0.0095. Therefore, our sample proportion, \(\hat{p} = 333/1771 = 0.188\) lies 1.26 standard deviations below the hypothesized population proportion, yielding a two-sided p-value of 0.2068 (Theory-Based Inference (TBI) applet). This p-value is not small and does not provide convincing evidence against the claim that \(\pi = 0.20\text{.}\) We would get sample proportions as or more extreme as 0.188 (meaning at least as far from 0.20) in about 21% of random samples from a population where 20% of teens have some hearing loss. Therefore, the headline seems appropriate. The confidence interval (TBI applet) tells us that we are 95% confident that between 17.0% and 20.6% of all U.S. teens have some form of hearing loss. (Do keep in mind that 0.20 is just one plausible value of \(\pi\text{.}\)) It is difficult to evaluate these values without knowing whether this percentage is increasing over time which we will investigate later.

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Subsection 4.4.1 Practice Problem 1.14

In 2018, the General Social Survey (GSS) used probability sampling methods to randomly select more than 2,000 adult Americans. One of the questions they asked was:

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In 2016, you remember that Clinton ran for president on the Democratic ticket against Trump for the Republicans. Do you remember for sure whether or not you voted in that election?
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Of the 2,181 respondents who were eligible to vote and remembered whether they had voted, 1523 (69.8%) said they voted. Let \(\pi\) represent the proportion of all eligible voters who would claim to have voted in the 2016 election. The United States Election Project (http://www.electproject.org/), reports that 136,753,936 ballots were cast for president that year, with 230,931,921 citizens eligible to vote, corresponding to 59.2% voter turnout. If we test \(H_0: \pi = 0.592\) vs. \(H_a: \pi \neq 0.592\text{,}\) what do we conclude?

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Checkpoint 4.4.10. GSS Voter Turnout Analysis.

Test the hypotheses using a \(z\)-test (see Section 4.5) and state your conclusion in context.

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You have attempted of activities on this page.

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