Plastic pollution is a major and growing problem, negatively affecting oceans and wildlife health. Our World in Data has a lot of great data at various levels including globally, per country, and over time. For this lab we focus on data from 2010.
Additionally, National Geographic recently ran a data visualization communication contest on plastic waste as seen here.
IMPORTANT: If there is no GitHub repo created for you for this assignment, it means I didn’t have your GitHub username as of when I assigned the homework. Please let me know your GitHub username asap, and I can create your repo.
Go to the course GitHub organization and locate your Lab 02 repo, which should be named lab-02-plastic-waste-YOUR_GITHUB_USERNAME
. Grab the URL of the repo, and clone it in RStudio. Refer to Lab 01 if you would like to see step-by-step instructions for cloning a repo into an RStudio project.
First, open the R Markdown document lab-02-plastic-waste.Rmd
and Knit it. Make sure it compiles without errors. The output will be in the file markdown .md
file with the same name.
We’ll use the tidyverse package for this analysis. Run the following code in the Console to load this package.
The dataset for this assignment can be found as a csv file in the data
folder of your repository. You can read it in using the following.
The variable descriptions are as follows:
code
: 3 Letter country codeentity
: Country namecontinent
: Continent nameyear
: Yeargdp_per_cap
: GDP per capita constant 2011 international $, rateplastic_waste_per_cap
: Amount of plastic waste per capita in kg/daymismanaged_plastic_waste_per_cap
: Amount of mismanaged plastic waste per capita in kg/daymismanaged_plastic_waste
: Tonnes of mismanaged plastic wastecoastal_pop
: Number of individuals living on/near coasttotal_pop
: Total population according to GapminderLet’s start by taking a look at the distribution of plastic waste per capita in 2010.
## Warning: Removed 51 rows containing non-finite values (stat_bin).
One country stands out as an unusual observation at the top of the distribution. One way of identifying this country is to filter the data for countries where plastic waste per capita is greater than 3.5 kg/person.
## # A tibble: 1 x 10
## code entity continent year gdp_per_cap plastic_waste_p…
## <chr> <chr> <chr> <dbl> <dbl> <dbl>
## 1 TTO Trini… North Am… 2010 31261. 3.6
## # … with 4 more variables: mismanaged_plastic_waste_per_cap <dbl>,
## # mismanaged_plastic_waste <dbl>, coastal_pop <dbl>, total_pop <dbl>
Did you expect this result? You might consider doing some research on Trinidad and Tobago to see why plastic waste per capita is so high there, or whether this is a data error.
From this point onwards the plots / output of the code won’t be printed in the lab, but you can run the code and view the results yourself.
Another way of visualizing numerical data is using density plots.
And compare distributions across continents by coloring density curves by continent.
ggplot(data = plastic_waste,
mapping = aes(x = plastic_waste_per_cap,
color = continent)) +
geom_density()
The resulting plot may be a little difficult to read, so let’s also fill the curves in with colors as well.
ggplot(data = plastic_waste,
mapping = aes(x = plastic_waste_per_cap,
color = continent,
fill = continent)) +
geom_density()
The overlapping colors make it difficult to tell what’s happening with the distributions in continents plotted first, and hence coverred by continents plotted over them. We can change the transparency level of the fill color to help with this. The alpha
argument takes values between 0 and 1: 0 is completely transparent and 1 is completely opaque. There is no way to tell what value will work best, so you just need to try a few.
ggplot(data = plastic_waste,
mapping = aes(x = plastic_waste_per_cap,
color = continent,
fill = continent)) +
geom_density(alpha = 0.7)
This still doesn’t look great…
Recreate the density plots above using a different (lower) alpha level that works better for displaying the density curves for all continents.
Describe why we defined the color
and fill
of the curves by mapping aesthetics of the plot but we defined the alpha
level as a characteristic of the plotting geom.
✅ ⬆️ Now is a good time to commit and push your changes to GitHub with an appropriate commit message. Make sure to commit and push all changed files so that your Git pane is cleared up afterwards.
And yet another way to visualize this relationship is using side-by-side box plots.
ggplot(data = plastic_waste,
mapping = aes(x = continent,
y = plastic_waste_per_cap)) +
geom_boxplot()
Remember that we use geom_point()
to make scatterplots.
Visualize the relationship between plastic waste per capita and mismanaged plastic waste per capita using a scatterplot. Describe the relationship.
Color the points in the scatterplot by continent. Does there seem to be any clear distinctions between continents with respect to how plastic waste per capita and mismanaged plastic waste per capita are associated?
Visualize the relationship between plastic waste per capita and total population as well as plastic waste per capita and coastal population. Do either of these pairs of variables appear to be more strongly linearly associated?
✅ ⬆️ Now is another good time to commit and push your changes to GitHub with an appropriate commit message. Make sure to commit and push all changed files so that your Git pane is cleared up afterwards.
Hint: The x-axis is a calculated variable. One country with plastic waste per capita over 3 kg/day has been filtered out. And the colors are from the viridis color palette. Take a look at the functions starting with scale_color_viridis_*
.
✅ ⬆️ Commit and push your changes to GitHub with an appropriate commit message again. Make sure to commit and push all changed files so that your Git pane is cleared up afterwards.