Inference for categorical data

In August of 2012, news outlets ranging from the Washington Post to the Huffington Post ran a story about the rise of atheism in America. The source for the story was a poll that asked people, “Irrespective of whether you attend a place of worship or not, would you say you are a religious person, not a religious person or a convinced atheist?” This type of question, which asks people to classify themselves in one way or another, is common in polling and generates categorical data. In this lab we take a look at the atheism survey and explore what’s at play when making inference about population proportions using categorical data.

The survey

To access the press release for the poll, conducted by WIN-Gallup International, click on the following link:

http://www.wingia.com/web/files/richeditor/filemanager/Global_INDEX_of_Religiosity_and_Atheism_PR__6.pdf

Take a moment to review the report then address the following questions.

In the first paragraph, several key findings are reported. Do these percentages appear to be sample statistics (derived from the data sample) or population parameters?

These percentages appear to apply to the population.
The title of the report is “Global Index of Religiosity and Atheism”. To generalize the report’s findings to the global human population, what must we assume about the sampling method? Does that seem like a reasonable assumption?

We must assume that the sample was random and representative of the global human population. The sample consisted of 50,000 people across 57 countries. There are over 7 billion people and 195 countries in the world today.

The data

Turn your attention to Table 6 (pages 15 and 16), which reports the sample size and response percentages for all 57 countries. While this is a useful format to summarize the data, we will base our analysis on the original data set of individual responses to the survey. Load this data set into R with the following command.

load("more/atheism.RData")

What does each row of Table 6 correspond to? What does each row of atheism correspond to?

Each row of the dataset corresponds to a single individual’s self-reported category.

To investigate the link between these two ways of organizing this data, take a look at the estimated proportion of atheists in the United States. Towards the bottom of Table 6, we see that this is 5%. We should be able to come to the same number using the atheism data.

Using the command below, create a new dataframe called us12 that contains only the rows in atheism associated with respondents to the 2012 survey from the United States. Next, calculate the proportion of atheist responses. Does it agree with the percentage in Table 6? If not, why?

5% of the responses in the dataset are of the category “atheist”.

In Table 6, 5% of the US sample is “a convinced atheist”.

Both of these percentages agree.

us12 <- subset(atheism, nationality == "United States" & year == "2012")

ath <- subset(us12, response=="atheist")
nonath <- subset(us12, response=="non-atheist")

(nrow(ath) / nrow(us12))*100

## [1] 4.99002

(nrow(nonath) / nrow(us12))*100

## [1] 95.00998

Inference on proportions

As was hinted at in Exercise 1, Table 6 provides statistics, that is, calculations made from the sample of 51,927 people. What we’d like, though, is insight into the population parameters. You answer the question, “What proportion of people in your sample reported being atheists?” with a statistic; while the question “What proportion of people on earth would report being atheists” is answered with an estimate of the parameter.

The inferential tools for estimating population proportion are analogous to those used for means in the last chapter: the confidence interval and the hypothesis test.

Write out the conditions for inference to construct a 95% confidence interval for the proportion of atheists in the United States in 2012. Are you confident all conditions are met?

Yes. The sample size is big enough, the observations are independent, and there are at least 10 expected successes and failures.

If the conditions for inference are reasonable, we can either calculate the standard error and construct the interval by hand, or allow the inference function to do it for us.

inference(us12$response, est = "proportion", type = "ci", method = "theoretical", 
          success = "atheist")

## Warning: package 'BHH2' was built under R version 3.4.4

## Single proportion -- success: atheist 
## Summary statistics:

## p_hat = 0.0499 ;  n = 1002 
## Check conditions: number of successes = 50 ; number of failures = 952 
## Standard error = 0.0069 
## 95 % Confidence interval = ( 0.0364 , 0.0634 )

Note that since the goal is to construct an interval estimate for a proportion, it’s necessary to specify what constitutes a “success”, which here is a response of "atheist".

Although formal confidence intervals and hypothesis tests don’t show up in the report, suggestions of inference appear at the bottom of page 7: “In general, the error margin for surveys of this kind is \(\pm\) 3-5% at 95% confidence”.

Based on the R output, what is the margin of error for the estimate of the proportion of the proportion of atheists in US in 2012?

Standard error = 0.0069

z* = 1.96 at a 95% confidence level

Margin of error = z * standard error

Margin of error = 0.013524
Using the inference function, calculate confidence intervals for the proportion of atheists in 2012 in two other countries of your choice, and report the associated margins of error. Be sure to note whether the conditions for inference are met. It may be helpful to create new data sets for each of the two countries first, and then use these data sets in the inference function to construct the confidence intervals.

I chose Japan and India.

Japan is 31% atheist, with 372 successes
- Conditions for inference are met
- 0.0132 standard error
- 0.025872 margin of error
India is 3% atheist, with 33 successes
- Conditions for inference are met
- 0.0052 standard error
- 0.10192 margin of error

  jpn12 <- subset(atheism, nationality == "Japan" & year == "2012")
  
  inference(jpn12$response, est = "proportion", type = "ci", method = "theoretical", 
          success = "atheist")

## Single proportion -- success: atheist 
## Summary statistics:

## p_hat = 0.3069 ;  n = 1212 
## Check conditions: number of successes = 372 ; number of failures = 840 
## Standard error = 0.0132 
## 95 % Confidence interval = ( 0.281 , 0.3329 )

  ind12 <- subset(atheism, nationality == "India" & year == "2012")

  inference(ind12$response, est = "proportion", type = "ci", method = "theoretical", success = "atheist")

## Single proportion -- success: atheist 
## Summary statistics:

## p_hat = 0.0302 ;  n = 1092 
## Check conditions: number of successes = 33 ; number of failures = 1059 
## Standard error = 0.0052 
## 95 % Confidence interval = ( 0.0201 , 0.0404 )

How does the proportion affect the margin of error?

Imagine you’ve set out to survey 1000 people on two questions: are you female? and are you left-handed? Since both of these sample proportions were calculated from the same sample size, they should have the same margin of error, right? Wrong! While the margin of error does change with sample size, it is also affected by the proportion.

Think back to the formula for the standard error: \(SE = \sqrt{p(1-p)/n}\). This is then used in the formula for the margin of error for a 95% confidence interval: \(ME = 1.96\times SE = 1.96\times\sqrt{p(1-p)/n}\). Since the population proportion \(p\) is in this \(ME\) formula, it should make sense that the margin of error is in some way dependent on the population proportion. We can visualize this relationship by creating a plot of \(ME\) vs. \(p\).

The first step is to make a vector p that is a sequence from 0 to 1 with each number separated by 0.01. We can then create a vector of the margin of error (me) associated with each of these values of p using the familiar approximate formula (\(ME = 2 \times SE\)). Lastly, we plot the two vectors against each other to reveal their relationship.

n <- 1000
p <- seq(0, 1, 0.01)
me <- 2 * sqrt(p * (1 - p)/n)
plot(me ~ p, ylab = "Margin of Error", xlab = "Population Proportion")

Describe the relationship between p and me.

The margin of error me reaches a peak when the population proportion p is around 0.5. It decreases as the proportion approaches both 0 and 1.

Success-failure condition

The textbook emphasizes that you must always check conditions before making inference. For inference on proportions, the sample proportion can be assumed to be nearly normal if it is based upon a random sample of independent observations and if both \(np \geq 10\) and \(n(1 - p) \geq 10\). This rule of thumb is easy enough to follow, but it makes one wonder: what’s so special about the number 10?

The short answer is: nothing. You could argue that we would be fine with 9 or that we really should be using 11. What is the “best” value for such a rule of thumb is, at least to some degree, arbitrary. However, when \(np\) and \(n(1-p)\) reaches 10 the sampling distribution is sufficiently normal to use confidence intervals and hypothesis tests that are based on that approximation.

We can investigate the interplay between \(n\) and \(p\) and the shape of the sampling distribution by using simulations. To start off, we simulate the process of drawing 5000 samples of size 1040 from a population with a true atheist proportion of 0.1. For each of the 5000 samples we compute \(\hat{p}\) and then plot a histogram to visualize their distribution.

p <- 0.1
n <- 1040
p_hats <- rep(0, 5000)

for(i in 1:5000){
  samp <- sample(c("atheist", "non_atheist"), n, replace = TRUE, prob = c(p, 1-p))
  p_hats[i] <- sum(samp == "atheist")/n
}

hist(p_hats, main = "p = 0.1, n = 1040", xlim = c(0, 0.18))

These commands build up the sampling distribution of \(\hat{p}\) using the familiar for loop. You can read the sampling procedure for the first line of code inside the for loop as, “take a sample of size \(n\) with replacement from the choices of atheist and non-atheist with probabilities \(p\) and \(1 - p\), respectively.” The second line in the loop says, “calculate the proportion of atheists in this sample and record this value.” The loop allows us to repeat this process 5,000 times to build a good representation of the sampling distribution.

Describe the sampling distribution of sample proportions at \(n = 1040\) and \(p = 0.1\). Be sure to note the center, spread, and shape.
Hint: Remember that R has functions such as mean to calculate summary statistics.

The sampling distribution appears close to normal, unimodal and symmetric. It has a mean of about 0.1 and a standard deviation of about 0.09.

summary(p_hats)

##    Min. 1st Qu.  Median    Mean 3rd Qu.    Max. 
## 0.07019 0.09327 0.09904 0.09969 0.10577 0.12981

sd(p_hats)

## [1] 0.009287382

Repeat the above simulation three more times but with modified sample sizes and proportions: for \(n = 400\) and \(p = 0.1\), \(n = 1040\) and \(p = 0.02\), and \(n = 400\) and \(p = 0.02\). Plot all four histograms together by running the par(mfrow = c(2, 2)) command before creating the histograms. You may need to expand the plot window to accommodate the larger two-by-two plot. Describe the three new sampling distributions. Based on these limited plots, how does \(n\) appear to affect the distribution of \(\hat{p}\)? How does \(p\) affect the sampling distribution?

The sampling distributions each have a mean of \(p\).

A larger \(n\) appeared to correspond to a larger spread, while a smaller \(n\) corresponded to a smaller spread.

p <- 0.1
n <- 400
p_hats1 <- rep(0, 5000)

for(i in 1:5000){
  samp <- sample(c("atheist", "non_atheist"), n, replace = TRUE, prob = c(p, 1-p))
  p_hats1[i] <- sum(samp == "atheist")/n
}

hist(p_hats1, main = "p = 0.1, n = 400", xlim = c(0, 0.25))

summary(p_hats1)

##    Min. 1st Qu.  Median    Mean 3rd Qu.    Max. 
## 0.05250 0.09000 0.10000 0.09976 0.11000 0.15500

sd(p_hats1)

## [1] 0.01504642

p <- 0.2
n <- 1040
p_hats2 <- rep(0, 5000)

for(i in 1:5000){
  samp <- sample(c("atheist", "non_atheist"), n, replace = TRUE, prob = c(p, 1-p))
  p_hats2[i] <- sum(samp == "atheist")/n
}

hist(p_hats2, main = "p = 0.2, n = 1040", xlim = c(0, 0.25))

summary(p_hats2)

##    Min. 1st Qu.  Median    Mean 3rd Qu.    Max. 
##  0.1548  0.1913  0.2000  0.2001  0.2087  0.2510

sd(p_hats2)

## [1] 0.01239902

p <- 0.02
n <- 400
p_hats3 <- rep(0, 5000)

for(i in 1:5000){
  samp <- sample(c("atheist", "non_atheist"), n, replace = TRUE, prob = c(p, 1-p))
  p_hats3[i] <- sum(samp == "atheist")/n
}

hist(p_hats3, main = "p = 0.02, n = 400", xlim = c(0, 0.25))

summary(p_hats3)

##    Min. 1st Qu.  Median    Mean 3rd Qu.    Max. 
## 0.00000 0.01500 0.02000 0.01988 0.02500 0.04750

sd(p_hats3)

## [1] 0.006976835

Once you’re done, you can reset the layout of the plotting window by using the command par(mfrow = c(1, 1)) command or clicking on “Clear All” above the plotting window (if using RStudio). Note that the latter will get rid of all your previous plots.

If you refer to Table 6, you’ll find that Australia has a sample proportion of 0.1 on a sample size of 1040, and that Ecuador has a sample proportion of 0.02 on 400 subjects. Let’s suppose for this exercise that these point estimates are actually the truth. Then given the shape of their respective sampling distributions, do you think it is sensible to proceed with inference and report margin of errors, as the reports does?

To proceed with inference, we need a minimum number of successes of failures.

Australia has \(0.1 \times 1040 = 104\) successes, which passes.

Ecuador has \(0.02 \times 400 = 8\) successes, which does not meet the 10 success threshold.

Furthermore, Ecuador’s sampling distribution appears skewed to the right.

We should not proceed with inference for Ecuador.

On your own

The question of atheism was asked by WIN-Gallup International in a similar survey that was conducted in 2005. (We assume here that sample sizes have remained the same.) Table 4 on page 13 of the report summarizes survey results from 2005 and 2012 for 39 countries.

Answer the following two questions using the inference function. As always, write out the hypotheses for any tests you conduct and outline the status of the conditions for inference.

a. Is there convincing evidence that Spain has seen a change in its atheism index between 2005 and 2012? Hint: Create a new data set for respondents from Spain. Form confidence intervals for the true proportion of athiests in both years, and determine whether they overlap.

We assume that the sample was collected randomly. The number of successes and failures are both above 10. The samples meet the conditions for inference.

Null hypothesis: Spain’s atheism index has not changed from 2005 to 2012.

Alternate hypothesis: Spain’s atheism index has changed from 2005 to 2012.

The 95% confidence intervals for the atheist index in 2005 is ( 0.083 , 0.1177 ), and in 2012 is ( 0.0734 , 0.1065 ). These two ranges have a lot of overlap, which leads us to accept the null hypothesis, that the index has not changed.

  sp05 <- subset(atheism, nationality == "Spain" & year == "2005")

  inference(sp05$response, est = "proportion", type = "ci", method = "theoretical", success = "atheist")

## Single proportion -- success: atheist 
## Summary statistics:

## p_hat = 0.1003 ;  n = 1146 
## Check conditions: number of successes = 115 ; number of failures = 1031 
## Standard error = 0.0089 
## 95 % Confidence interval = ( 0.083 , 0.1177 )

  sp12 <- subset(atheism, nationality == "Spain" & year == "2012")

  inference(sp12$response, est = "proportion", type = "ci", method = "theoretical", success = "atheist")

## Single proportion -- success: atheist 
## Summary statistics:

## p_hat = 0.09 ;  n = 1145 
## Check conditions: number of successes = 103 ; number of failures = 1042 
## Standard error = 0.0085 
## 95 % Confidence interval = ( 0.0734 , 0.1065 )

**b.** Is there convincing evidence that the United States has seen a change in its atheism index between 2005 and 2012?


****

We assume that the sample was collected randomly. The number of successes and failures are both above 10. The samples meet the conditions for inference.

Null hypothesis: The U.S. atheism index has not changed from 2005 to 2012.

Alternate hypothesis: The U.S. atheism index has changed from 2005 to 2012.

The 95% confidence intervals for the U.S. atheist index in 2005 is ( 0.0038 , 0.0161 ), and in 2012 is ( 0.0364 , 0.0634 ). These two ranges do not overlap, which leads us to reject the null hypothesis as true. The atheist index has indeed changed from 2005 to 2012 in the United States.

  us05 <- subset(atheism, nationality == "United States" & year == "2005")

  inference(us05$response, est = "proportion", type = "ci", method = "theoretical", success = "atheist")

## Single proportion -- success: atheist 
## Summary statistics:

## p_hat = 0.01 ;  n = 1002 
## Check conditions: number of successes = 10 ; number of failures = 992 
## Standard error = 0.0031 
## 95 % Confidence interval = ( 0.0038 , 0.0161 )

  us12 <- subset(atheism, nationality == "United States" & year == "2012")

  inference(us12$response, est = "proportion", type = "ci", method = "theoretical", success = "atheist")

## Single proportion -- success: atheist 
## Summary statistics:

## p_hat = 0.0499 ;  n = 1002 
## Check conditions: number of successes = 50 ; number of failures = 952 
## Standard error = 0.0069 
## 95 % Confidence interval = ( 0.0364 , 0.0634 )

If in fact there has been no change in the atheism index in the countries listed in Table 4, in how many of those countries would you expect to detect a change (at a significance level of 0.05) simply by chance?
Hint: Look in the textbook index under Type 1 error.

A Type 1 error is a “false positive” – an incorrect rejection of a true null hypothesis.

If we are looking at a signifiance level of 0.05, then we expect that 5% of countries will be false positives and reject the null.

There are 40 countries in table 4, so we expect \(40 \times 0.05 = 2\) countries to detect a change simply by chance.
Suppose you’re hired by the local government to estimate the proportion of residents that attend a religious service on a weekly basis. According to the guidelines, the estimate must have a margin of error no greater than 1% with 95% confidence. You have no idea what to expect for \(p\). How many people would you have to sample to ensure that you are within the guidelines?
Hint: Refer to your plot of the relationship between \(p\) and margin of error. Do not use the data set to answer this question.

According to the plot, margin of error is maximized when \(p=0.05\). To get a margin of error of 0.01, we set the margin of error formula equal to 0.01 and solve for \(n\). Since we are working at a 95% confidence level, \(z^*\) will be 1.96.

\(ME = 1.96 \times \sqrt\frac{p(1 - p)}{n}\)

\(0.01 = 1.96 \times \sqrt\frac{0.01}{n}\)

\(\frac{0.01}{1.96} = \sqrt\frac{0.01}{n}\)

\(\frac{0.0001}{3.8416} = \frac{0.01}{n}\)

\(n = 0.01 \times \frac{3.8416}{0.0001}\)

\(n = 384.16\)

0.01*(3.8416/0.0001)

## [1] 384.16

This is a product of OpenIntro that is released under a Creative Commons Attribution-ShareAlike 3.0 Unported. This lab was written for OpenIntro by Andrew Bray and Mine Çetinkaya-Rundel.