While it will be important to focus on theory, I want to explain the ggplot2 package because I will be using it throughout the rest of this series. Knowing how it works will keep the focus on the results rather than the code. It’s an incredibly powerful package and once you wrap your head around what it’s doing, your life will change for the better! There are a lot of tools out there which provide better charts, graphs and ease of use (i.e. plot.ly, d3.js, Qlik, Tableau), but ggplot2 is still a fantastic resource and I use it all of the time.
In case you missed it, here’s a link to Data Visualization – Part 1
Why would you use ggplot2?
- More robust plotting than the base plot package
- Better control over aesthetics – colors, axes, background, etc.
- Variable Mapping (aes)
- Automatic aggregation of data
- Built in formulas & plotting (geom_smooth)
- The list goes on and on…
Basically, ggplot2 allows for a lot more customization of plots with a lot less code (the rest of it is behind the scenes). Once you are used to the syntax, there’s no going back. It’s faster and easier.
Why wouldn’t you use ggplot2?
- A bit of a learning curve
- Lack of user interactivity with the plots
Fundamentally, ggplot2 gives the user the ability to start a plot and layer everything in. There are many ways to accomplish the same thing, so figure out what makes sense for you and stick to it.
A Basic Example: Unemployment Over Time
library(dplyr) library(ggplot2) # Load the economics data from ggplot2 data(economics,package='ggplot2')
# Take a look at the format of the data head(economics)
## # A tibble: 6 × 6 ## date pce pop psavert uempmed unemploy ## <date> <dbl> <int> <dbl> <dbl> <int> ## 1 1967-07-01 507.4 198712 12.5 4.5 2944 ## 2 1967-08-01 510.5 198911 12.5 4.7 2945 ## 3 1967-09-01 516.3 199113 11.7 4.6 2958 ## 4 1967-10-01 512.9 199311 12.5 4.9 3143 ## 5 1967-11-01 518.1 199498 12.5 4.7 3066 ## 6 1967-12-01 525.8 199657 12.1 4.8 3018
# Create the plot ggplot(data = economics) + geom_line(aes(x = date, y = unemploy))
What happened to get that?
ggplot(economics)loaded the data frame
+tells ggplot() that there is more to be added to the plot
geom_line()defined the type of plot
aes(x = date, y = unemploy)mapped the variables
aes() portion is what typically throws new users off but is my favorite feature of ggplot2. In simple terms, this is what “auto-magically” brings your plot to life. You are telling ggplot2, “I want ‘date’ to be on the x-axis and ‘unemploy’ to be on the y-axis.” It’s pretty straightforward in this case but there are more complex use cases as well.
Side Note: you could have achieved the same result by mapping the variables in the ggplot() function rather than in geom_line():
ggplot(data = economics, aes(x = date, y = unemploy)) + geom_line()
Here’s the basic formula for success:
- Everything in ggplot2 starts with
+to add on every element thereafter
- Include your data frame (economics) in a ggplot function:
ggplot(data = economics)
- Input the type of plot you would like (i.e. line chart of unemployment over time):
+ geom_line(aes(x = date, y = unemploy))
- “geom” stands for “geometric object” and determines the type of object (there can be more than one type per plot)
- There are a lot of types of geometric objects – check them out here
- Add in layers and utilize
I’ll go through some of the examples from the Top 50 ggplot2 Visualizations Master List. I will be using their examples but I will also explain what’s going on.
Note: I believe the intention of the author of the Top 50 ggplot2 Visualizations Master List was to illustrate how to use ggplot2 rather than doing a full demonstration of what important data visualization techniques are – so keep that in mind as I go through these examples. Some of the visuals do not line up with my best practices addressed in my first post on data visualization.
As usual, some packages must be loaded.
library(reshape2) library(lubridate) library(dplyr) library(tidyr) library(ggplot2) library(scales) library(gridExtra)
This is one of the most visually powerful tool for data analysis. However, you have to be careful when using it because it’s primarily used by people doing analysis and not reporting (depending on what industry you’re in).
The author of this chart was looking for a correlation between area and population.
# Use the "midwest" data from ggplot2 data("midwest", package = "ggplot2") head(midwest)
## # A tibble: 6 × 28 ## PID county state area poptotal popdensity popwhite popblack ## <int> <chr> <chr> <dbl> <int> <dbl> <int> <int> ## 1 561 ADAMS IL 0.052 66090 1270.9615 63917 1702 ## 2 562 ALEXANDER IL 0.014 10626 759.0000 7054 3496 ## 3 563 BOND IL 0.022 14991 681.4091 14477 429 ## 4 564 BOONE IL 0.017 30806 1812.1176 29344 127 ## 5 565 BROWN IL 0.018 5836 324.2222 5264 547 ## 6 566 BUREAU IL 0.050 35688 713.7600 35157 50 ## # ... with 20 more variables: popamerindian <int>, popasian <int>, ## # popother <int>, percwhite <dbl>, percblack <dbl>, percamerindan <dbl>, ## # percasian <dbl>, percother <dbl>, popadults <int>, perchsd <dbl>, ## # percollege <dbl>, percprof <dbl>, poppovertyknown <int>, ## # percpovertyknown <dbl>, percbelowpoverty <dbl>, ## # percchildbelowpovert <dbl>, percadultpoverty <dbl>, ## # percelderlypoverty <dbl>, inmetro <int>, category <chr>
Here’s the most basic version of the scatter plot
This can be called by
geom_point() in ggplot2
# Scatterplot ggplot(data = midwest, aes(x = area, y = poptotal)) + geom_point() #ggplot
Here’s version with some additional features
While the addition of the size of the points and color don’t add value, it does show the level of customization that’s possible with ggplot2.
ggplot(data = midwest, aes(x = area, y = poptotal)) + geom_point(aes(col=state, size=popdensity)) + geom_smooth(method="loess", se=F) + xlim(c(0, 0.1)) + ylim(c(0, 500000)) + labs(subtitle="Area Vs Population", y="Population", x="Area", title="Scatterplot", caption = "Source: midwest")
ggplot(data = midwest, aes(x = area, y = poptotal)) +
Inputs the data and maps x and y variables as area and poptotal.
geom_point(aes(col=state, size=popdensity)) +
Creates a scatterplot and maps the color and size of points to state and popdensity.
geom_smooth(method="loess", se=F) +
Creates a smoothing curve to fit the data.
method is the type of fit and
se determines whether or not to show error bars.
xlim(c(0, 0.1)) +
Sets the x-axis limits.
ylim(c(0, 500000)) +
Sets the y-axis limits.
labs(subtitle="Area Vs Population",
caption = "Source: midwest")
Changes the labels of the subtitle, y-axis, x-axis, title and caption.
Notice that the legend was automatically created and placed on the lefthand side. This is also highly customizable and can be changed easily.
The Density Plot
Density plots are a great way to see how data is distributed. They are similar to histograms in a sense, but show values in terms of percentage of the total. In this example, the author used the mpg data set and is looking to see the different distributions of City Mileage based off of the number of cylinders the car has.
# Examine the mpg data set head(mpg)
## # A tibble: 6 × 11 ## manufacturer model displ year cyl trans drv cty hwy fl ## <chr> <chr> <dbl> <int> <int> <chr> <chr> <int> <int> <chr> ## 1 audi a4 1.8 1999 4 auto(l5) f 18 29 p ## 2 audi a4 1.8 1999 4 manual(m5) f 21 29 p ## 3 audi a4 2.0 2008 4 manual(m6) f 20 31 p ## 4 audi a4 2.0 2008 4 auto(av) f 21 30 p ## 5 audi a4 2.8 1999 6 auto(l5) f 16 26 p ## 6 audi a4 2.8 1999 6 manual(m5) f 18 26 p ## # ... with 1 more variables: class <chr>
Sample Density Plot
g = ggplot(mpg, aes(cty)) g + geom_density(aes(fill=factor(cyl)), alpha=0.8) + labs(title="Density plot", subtitle="City Mileage Grouped by Number of cylinders", caption="Source: mpg", x="City Mileage", fill="# Cylinders")
You’ll notice one immediate difference here. The author decided to create a the object
g to equal
ggplot(mpg, aes(cty)) – this is a nice trick and will save you some time if you plan on keeping
ggplot(mpg, aes(cty)) as the fundamental plot and simply exploring other visualizations on top of it. It is also handy if you need to save the output of a chart to an image file.
ggplot(mpg, aes(cty)) loads the mpg data and
aes(x = cty)
g + geom_density(aes(fill=factor(cyl)), alpha=0.8) +
geom_density kicks off a density plot and the mapping of
cyl is used for colors.
alpha is the transparency/opacity of the area under the curve.
subtitle="City Mileage Grouped by Number of cylinders",
Labeling is cleaned up at the end.
How would you use your new knowledge to see the density by class instead of by number of cylinders?
g = ggplot(mpg, aes(cty)) has already been established.
g + geom_density(aes(fill=factor(class)), alpha=0.8) + labs(title="Density plot", subtitle="City Mileage Grouped by Class", caption="Source: mpg", x="City Mileage", fill="Class")
Notice how I didn’t have to write out
ggplot() again because it was already stored in the object
How could we show the city mileage in a histogram?
g = ggplot(mpg,aes(cty)) g + geom_histogram(bins=20) + labs(title="Histogram", caption="Source: mpg", x="City Mileage")
geom_histogram(bins=20) plots the histogram. If
bins isn’t set, ggplot2 will automatically set one.
The Bar/Column Chart
For all intensive purposes, bar and column charts are essentially the same. Technically, the term “column chart” can be used when the bars run vertically. The author of this chart was simply looking at the frequency of the vehicles listed in the data set.
#Data Preparation freqtable <- table(mpg$manufacturer) df <- as.data.frame.table(freqtable) head(df)
## Var1 Freq ## 1 audi 18 ## 2 chevrolet 19 ## 3 dodge 37 ## 4 ford 25 ## 5 honda 9 ## 6 hyundai 14
#Set a theme theme_set(theme_classic()) g <- ggplot(df, aes(Var1, Freq)) g + geom_bar(stat="identity", width = 0.5, fill="tomato2") + labs(title="Bar Chart", subtitle="Manufacturer of vehicles", caption="Source: Frequency of Manufacturers from 'mpg' dataset") + theme(axis.text.x = element_text(angle=65, vjust=0.6))
The addition of
theme_set(theme_classic()) adds a preset theme to the chart. You can create your own or select from a large list of themes. This can help set your work apart from others and save a lot of time.
However, theme_set() is different than the
theme(axis.text.x = element_text(angle=65, vjust=0.6)) the one used inside the plot itself in this case. The author decided to tilt the text along the x-axis.
vjust=0.6 changes how far it is spaced away from the axis line.
geom_bar() there is another new piece of information:
stat="identity" which tells ggplot to use the actual value of
You may also notice that ggplot arranged all of the data in alphabetical order based off of the manufacturer. If you want to change the order, it’s best to use the
reorder() function. This next chart will use the
coord_flip() to orient the chart differently.
g <- ggplot(df, aes(reorder(Var1,Freq), Freq)) g + geom_bar(stat="identity", width = 0.5, fill="tomato2") + labs(title="Bar Chart", x = 'Manufacturer', subtitle="Manufacturer of vehicles", caption="Source: Frequency of Manufacturers from 'mpg' dataset") + theme(axis.text.x = element_text(angle=65, vjust=0.6)) + coord_flip()
Let’s continue with bar charts – what if we wanted to see what
hwy looked like by
manufacturerand in terms of
g = ggplot(mpg,aes(x=manufacturer,y=hwy,col=factor(cyl),fill=factor(cyl))) g + geom_bar(stat='identity', position='dodge') + theme(axis.text.x = element_text(angle=65, vjust=0.6))
position='dodge' had to be used because the default setting is to stack the bars,
'dodge'places them side by side for comparison.
Despite the fact that the chart did what I wanted, it is very difficult to read due to how many manufacturers there are. This is where the
facet_wrap() feature comes in handy.
theme_set(theme_bw()) g = ggplot(mpg,aes(x=factor(cyl),y=hwy,col=factor(cyl),fill=factor(cyl))) g + geom_bar(stat='identity', position='dodge') + facet_wrap(~manufacturer)
This created a much nicer view of the information. It “auto-magically” split everything out by manufacturer!
Another nice feature of ggplot2 is the integration with maps and spatial plotting. In this simple example, I wanted to plot a few cities in Colorado and draw a border around them. Other than the addition of the map, ggplot simply places the dots directly on the locations via their longitude and latitude “auto-magically.”
This map is created with
ggmap which utilizes Google Maps API.
library(ggmap) library(ggalt) foco <- geocode("Fort Collins, CO") # get longitude and latitude # Get the Map ---------------------------------------------- colo_map <- qmap("Colorado, United States",zoom = 7, source = "google") # Get Coordinates for Places --------------------- colo_places <- c("Fort Collins, CO", "Denver, CO", "Grand Junction, CO", "Durango, CO", "Pueblo, CO") places_loc <- geocode(colo_places) # get longitudes and latitudes # Plot Open Street Map ------------------------------------- colo_map + geom_point(aes(x=lon, y=lat), data = places_loc, alpha = 0.7, size = 7, color = "tomato") + geom_encircle(aes(x=lon, y=lat), data = places_loc, size = 2, color = "blue")
I hope you learned a lot about the basics of ggplot2 in this. It’s extremely powerful but yet easy to use once you get the hang of it. The best way to really learn it is to try it out. Find some data on your own and try to manipulate it and get it plotted. Without a doubt, you will have all kinds of errors pop up, data you expect to be plotted won’t show up, colors and fills will be different, etc. However, your visualizations will be leveled-up!
- Determining whether or not you need a visualization
- Choosing the type of plot to use depending on the use case
- Visualization beyond the standard charts and graphs