Editing Statistics and Statistical Programming (Fall 2020)/pset5
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:: Aronow PM, Karlan D, Pinson LE. (2018). The effect of images of Michelle Obama’s face on trick-or-treaters’ dietary choices: A randomized control trial. PLoS ONE 13(1): e0189693. [https://doi.org/10.1371/journal.pone.0189693 https://doi.org/10.1371/journal.pone.0189693] | :: Aronow PM, Karlan D, Pinson LE. (2018). The effect of images of Michelle Obama’s face on trick-or-treaters’ dietary choices: A randomized control trial. PLoS ONE 13(1): e0189693. [https://doi.org/10.1371/journal.pone.0189693 https://doi.org/10.1371/journal.pone.0189693] | ||
: '''PC1.''' [https://dataverse.harvard.edu/dataset.xhtml?persistentId=doi:10.7910/DVN/2NJV2P Download the dataset]. You may want to familiarize yourself with the experimental treatment and key details of the research design from the (short) article linked above. | |||
:'''PC2.''' Import the data into R. You may need to install the <code>readstata13</code> package and identify an appropriate function with which to do so. | |||
:'''PC3.''' Get to know your dataset. Take a look at the codebook if necessary and make sure you have the two columns of the dataset that correspond to the experimental treatment (being presented with Michelle Obama's face or not) and the outcome (whether or not trick-or-treaters picked up fruit). Don't worry about any of the other measures for now. | |||
:'''PC4.''' Create a two-way contingency table summarizing these two variables. Make sure your table has easily understandable column and row names. | |||
Get to know your dataset. Take a look at the codebook if necessary and make sure you have the two columns of the dataset that correspond to the experimental treatment (being presented with Michelle Obama's face or not) and the outcome (whether or not trick-or-treaters picked up fruit). Don't worry about any of the other measures for now. | :'''PC5.''' Construct and perform a statistical hypothesis test to determine whether or not the two groups are dependent. State your hypotheses clearly. Report and interpret the results of your test and be prepared to discuss your findings. Please note that the paper uses a variety of techniques including linear regression and incorporates other variables, but you should use estimators and tests we read about in ''OpenIntro'' §6 last week. | ||
:'''PC6.''' Try to reproduce the top panel of Figure 1 using the same two columns of the dataset (by ignoring year and the other variables we are, in effect, working with the "pooled" sample). If you cannot reproduce that portion of the figure (or something like it), try to at least reproduce the values presented in it. | |||
Create a two-way contingency table summarizing these two variables. Make sure your table has easily understandable column and row names. | :'''PC7.''' We've used RMarkdown to handle reproducible data analysis and export thus far, but it's also often important to export tables directly into your word processor or typesetting software without cutting and pasting the contents of individual cells by hand. Write R code that exports the ''output'' of your table from PC4. There are a bunch of functions you can use to do this. I would likely use the <code>xtable</code> package to generate HTML and/or LaTeX output, but I think that the Base-R <code>write.table()</code> function for export into Excel could do the job just as well. | ||
Construct and perform a statistical hypothesis test to determine whether or not the two groups are dependent. State your hypotheses clearly. Report and interpret the results of your test and be prepared to discuss your findings. Please note that the paper uses a variety of techniques including linear regression and incorporates other variables, but you should use estimators and tests we read about in ''OpenIntro'' §6 last week. | |||
Try to reproduce the top panel of Figure 1 using the same two columns of the dataset (by ignoring year and the other variables we are, in effect, working with the "pooled" sample). If you cannot reproduce that portion of the figure (or something like it), try to at least reproduce the values presented in it. | |||
We've used RMarkdown to handle reproducible data analysis and export thus far, but it's also often important to export tables directly into your word processor or typesetting software without cutting and pasting the contents of individual cells by hand. Write R code that exports the ''output'' of your table from PC4. There are a bunch of functions you can use to do this. I would likely use the <code>xtable</code> package to generate HTML and/or LaTeX output, but I think that the Base-R <code>write.table()</code> function for export into Excel could do the job just as well. | |||
== Empirical Paper Questions (with Statistical Questions baked in) == | == Empirical Paper Questions (with Statistical Questions baked in) == | ||
These questions are for the Buechley and Hill paper on LilyPad Arduino: | |||
: '''EQ1.''' Focus on the statistical test conducted in ''Study 1'': | |||
:: (a) What is the unit of analysis? What is the dependent variable? The independent variable? What are groups being compared in the test? Is it a one-way or two-way design? | |||
:: (a) What is the unit of analysis? What is the dependent variable? The independent variable? What groups | |||
:: (b) Why bother with the statistical test? Why is this an appropriate statistical procedure? | :: (b) Why bother with the statistical test? Why is this an appropriate statistical procedure? | ||
:: (c) What is the null hypothesis being tested? What is the alternative hypothesis? | :: (c) What is the null hypothesis being tested? What is the alternative hypothesis? | ||
:: (d) Summarize/restate the results in both statistical and substantive terms. Assess the results: How convincing do you find them? What should we take away from this analysis? | :: (d) Summarize/restate the results in both statistical and substantive terms. Assess the results: How convincing do you find them? What should we take away from this analysis? | ||
And these are about the Shaw and Benkler paper on political blogs: | |||
: '''EQ2.''' Focus on Table 3 and Figure 2: | |||
:: (a) What statistical procedure produced the p-value in Table 3? State the null/alternative hypotheses being tested. | :: (a) What statistical procedure produced the p-value in Table 3? State the null/alternative hypotheses being tested. | ||
:: (b) How convincing do you find these results? What are some reasons to be skeptical? | :: (b) How convincing do you find these results? What are some reasons to be skeptical? | ||
:: (c) Reproduce Figure 2 using the data in Table 3. One thing that's missing from that figure is error bars. Based on the reading from Reinhart §5, what type of error bars do you think you should use? Figure out how to calculate the error bars and figure out if they overlap? What does that tell us? (Bonus: figure out how to add error bars to the bar plot) | :: (c) Reproduce Figure 2 using the data in Table 3. One thing that's missing from that figure is error bars. Based on the reading from Reinhart §5, what type of error bars do you think you should use? Figure out how to calculate the error bars and figure out if they overlap? What does that tell us? (Bonus: figure out how to add error bars to the bar plot) | ||
:: (d) Should we be concerned about the base rate fallacy described in Reinhart §4? Why or why not? | :: (d) Should we be concerned about the base rate fallacy described in Reinhart §4? Why or why not? | ||
