5 Data Wrangling via dplyr
Let’s briefly recap where we have been so far and where we are headed. In Chapter 4, we discussed what it means for data to be tidy. We saw that this refers to observations corresponding to rows and variables being stored in columns (one variable for every column). The entries in the data frame correspond to different combinations of observations (specific instances of observational units) and variables. In the flights
data frame, we saw that each row corresponds to a different flight leaving New York City. In other words, the observational unit of the flights
tidy data frame is a flight. The variables are listed as columns, and for flights
these columns include both quantitative variables like dep_delay
and distance
and also categorical variables like carrier
and origin
. An entry in the table corresponds to a particular flight on a given day and a particular value of a given variable representing that flight.
Armed with this knowledge and looking back on Chapter 3, we see that organizing data in this tidy way makes it easy for us to produce graphics, specifically a set of 5 common graphics we termed the 5 Named Graphics (5NG):
- scatterplots
- linegraphs
- boxplots
- histograms
- barplots
We can simply specify what variable/column we would like on one axis, (if applicable) what variable we’d like on the other axis, and what type of plot we’d like to make by specifying the geom
etric object in question. We can also vary aesthetic attributes of the geometric objects in question (points, lines, bar), such as the size and color, along the values of another variable in this tidy dataset. Recall the Gapminder example from Figure 3.1.
Lastly, in a few spots in Chapter 3 and Chapter 4, we hinted at some ways to summarize and wrangle data to suit your needs, using the filter()
and inner_join()
functions. This chapter expands on these functions by giving a variety of examples using what we term the Five Main Verbs (5MV) in the dplyr
package (Wickham et al. 2017).
Needed packages
Let’s load all the packages needed for this chapter (this assumes you’ve already installed them). If needed, read Section 2.3 for information on how to install and load R packages.
library(dplyr)
library(ggplot2)
library(nycflights13)
library(knitr)
5.1 The pipe %>%
Before we introduce the five main verbs, we first introduce the pipe operator (%>%
). Just as the +
sign was used to add layers to a plot created using ggplot()
, the pipe operator allows us to chain together dplyr
data wrangling functions. The pipe operator can be read as “then”. The %>%
operator allows us to go from one step in dplyr
to the next easily so we can, for example:
filter
our data frame to only focus on a few rows thengroup_by
another variable to create groups thensummarize
this grouped data to calculate the mean for each level of the group.
The piping syntax will be our major focus throughout the rest of this book and you’ll find that you’ll quickly be addicted to the chaining with some practice.
5.2 Five Main Verbs - The 5MV
The d
in dplyr
stands for data frames, so the functions in dplyr are built for working with objects of the data frame type. For now, we focus on the 5MV: the five most commonly used functions that help wrangle and summarize data. A description of these verbs follows, with each subsection devoted to an example of that verb, or a combination of a few verbs, in action.
filter
: Pick rows based on conditions about their valuessummarize
: Create summary measures of variables either- over the entire data frame or
- over groups of observations on variables using
group_by
mutate
: Create a new variable in the data frame by mutating existing onesarrange
: Arrange/sort the rows based on one or more variables
Just as we had the Five Named Graphs for data visualization using ggplot2
in Chapter 3, we have the 5MV here (The Five Main Verbs in dplyr
) for data wrangling. All of the 5MVs follow the same syntax, with the argument before the pipe %>%
being the name of the data frame, then the name of the verb, followed with other arguments specifying which criteria you’d like the verb to work with in parentheses.
Keep in mind, there are more advanced functions than just these five and you’ll see some examples of this near the end of this chapter in 5.4, but with the 5MV you’ll be able to perform a broad array of data wrangling tasks.
5.2.1 5MV#1: Filter observations using filter
The filter
function here works much like the “Filter” option in Microsoft Excel; it allows you to specify criteria about values of a variable in your dataset and then chooses only those rows that match that criteria. We begin by focusing only on flights from New York City to Portland, Oregon. The dest
code (or airport code) for Portland, Oregon is "PDX"
. Run the following and look at the resulting spreadsheet to ensure that only flights heading to Portland are chosen here:
portland_flights <- flights %>%
filter(dest == "PDX")
View(portland_flights)
Note the following:
- The ordering of the commands:
- Take the data frame
flights
then filter
the data frame so that only those where thedest
equals"PDX"
are included.
- Take the data frame
- The double equal sign
==
for testing for equality, and not=
. You are almost guaranteed to make the mistake at least once of only including one equals sign.
You can combine multiple criteria together using operators that make comparisons:
|
corresponds to “or”&
corresponds to “and”
We can often skip the use of &
and just separate our conditions with a comma. You’ll see this in the example below.
In addition, you can use other mathematical checks (similar to ==
):
>
corresponds to “greater than”<
corresponds to “less than”>=
corresponds to “greater than or equal to”<=
corresponds to “less than or equal to”!=
corresponds to “not equal to”
To see many of these in action, let’s select all flights that left JFK airport heading to Burlington, Vermont ("BTV"
) or Seattle, Washington ("SEA"
) in the months of October, November, or December. Run the following
btv_sea_flights_fall <- flights %>%
filter(origin == "JFK", (dest == "BTV" | dest == "SEA"), month >= 10)
View(btv_sea_flights_fall)
Note: even though colloquially speaking one might say “all flights leaving Burlington, Vermont and Seattle, Washington,” in terms of computer logical operations, we really mean “all flights leaving Burlington, Vermont or Seattle, Washington.” For a given row in the data, dest
can be “BTV”, “SEA”, or something else, but not “BTV” and “SEA” at the same time.
Another example uses the !
to pick rows that don’t match a condition. The !
can be read as “not”. Here we are selecting rows corresponding to flights that didn’t go to Burlington, VT or Seattle, WA.
not_BTV_SEA <- flights %>%
filter(!(dest == "BTV" | dest == "SEA"))
View(not_BTV_SEA)
As a final note we point out that filter()
should often be the first verb you’ll apply to your data. This cleans your dataset to only those rows you care about, or put differently, it narrows down the scope to just the observations your care about.
Learning check
(LC5.1) What’s another way using the “not” operator !
we could filter only the rows that are not going to Burlington, VT nor Seattle, WA in the flights
data frame? Test this out using the code above.
5.2.2 5MV#2: Summarize variables using summarize
The next common task when working with data is to be able to summarize data: take a large number of values and summarize then with a single value. While this may seem like a very abstract idea, something has simple as the sum, the smallest value, and the largest values are all summaries of a large number of values.
We can calculate the standard deviation and mean of the temperature variable temp
in the weather
data frame of nycflights13
in one step using the summarize
(or equivalently using the UK spelling summarise
) function in dplyr
(See Appendix A):
summary_temp <- weather %>%
summarize(mean = mean(temp), std_dev = sd(temp))
kable(summary_temp)
mean | std_dev |
---|---|
NA | NA |
We’ve created a small data frame here called summary_temp
that includes both the mean
and the std_dev
of the temp
variable in weather
. Notice as shown in Figures 5.2 and 5.3, the data frame weather
went from many rows to a single row of just the summary values in the data frame summary_temp
.
But why are the values returned NA
? This stands for “not available or not applicable” and is how R encodes missing values; if in a data frame for a particular row and column no value exists, NA
is stored instead. Furthermore, by default any time you try to summarize a number of values (using mean()
and sd()
for example) that has one or more missing values, then NA
is returned.
Values can missing missing for many reasons. Perhaps the data was collected but someone forgot to enter it? Perhaps the data was not collected at all because it was too difficult? Perhaps there was an erroneous value that someone entered that has been correct to read as missing? You’ll often encounter issues with missing values.
You can summarize all non-missing values by setting the na.rm
argument to TRUE (rm
is short for “remove”). This will remove any NA
missing values and only return the summary value for all non-missing values. So the code below computes the mean and standard deviation of all non-missing values. Notice how the na.rm=TRUE
are set as arguments to the mean()
and sd()
functions, and not to the summarize()
function.
summary_temp <- weather %>%
summarize(mean = mean(temp, na.rm = TRUE), std_dev = sd(temp, na.rm = TRUE))
kable(summary_temp)
mean | std_dev |
---|---|
55.2 | 17.78 |
It is not good practice to include a na.rm = TRUE
in your summary commands by default; you should attempt to run them without this argument. This is because removing missing data can have an impact on your analyses. In fact, an entire branch of the field of statistics deals with missing data. The take away point is that na.rm = TRUE
should only be used after you aware of the implications of its use (see the Learning Checks below for an example).
What other summary functions can we use inside the summarize()
verb? Any function in R that takes a vector of values and returns just one. Here are just a few:
min()
andmax()
: the minimum and maximum values respectivelyIQR()
: Interquartile rangesum()
: the sumn()
: a count of the number of rows/observations in each group. This particular summary function will make more sense whengroup_by()
is covered in Subsection 5.2.3.
Learning check
(LC5.2) Say a doctor is studying the effect of smoking on lung cancer for a large number of patients who have records measured at five year intervals. She notices that a large number of patients have missing data points because the patient has died, so she chooses to ignore these patients in his analysis. What is wrong with this doctor’s approach?
(LC5.3) Modify the above summarize
function to create summary_temp
to also use the n()
summary function: summarize(count = n())
. What does the returned value correspond to?
(LC5.4) Why doesn’t the following code work? Run the code line by line instead of all at once, and then look at the data. In other words, run summary_temp <- weather %>% summarize(mean = mean(temp, na.rm = TRUE))
first.
summary_temp <- weather %>%
summarize(mean = mean(temp, na.rm = TRUE)) %>%
summarize(std_dev = sd(temp, na.rm = TRUE))
5.2.3 5MV#3: Group rows using group_by
It’s often more useful to summarize a variable based on the groupings of another variable. Let’s say, we are interested in the mean and standard deviation of temperatures but grouped by month. To be more specific: we want the mean and standard deviation of temperatures
- split by month.
- sliced by month.
- aggregated by month.
- collapsed over month.
Run the following code (recall the discussion of the kable()
function from the knitr
package in Subsection 2.4.3):
summary_monthly_temp <- weather %>%
group_by(month) %>%
summarize(mean = mean(temp, na.rm = TRUE),
std_dev = sd(temp, na.rm = TRUE))
kable(summary_monthly_temp)
month | mean | std_dev |
---|---|---|
1 | 35.64 | 10.185 |
2 | 34.15 | 6.940 |
3 | 39.81 | 6.225 |
4 | 51.67 | 8.785 |
5 | 61.59 | 9.609 |
6 | 72.14 | 7.603 |
7 | 80.01 | 7.148 |
8 | 74.40 | 5.171 |
9 | 67.43 | 8.476 |
10 | 60.03 | 8.830 |
11 | 45.11 | 10.502 |
12 | 38.37 | 9.941 |
This code is identical to the previous code that created summary_temp
, with an extra group_by(month)
added. Grouping the weather
dataset by month
and then passing this new data frame into summarize
yields a data frame that shows the mean and standard deviation of temperature for each month in New York City. Note: Since each row in summary_monthly_temp
represents a summary of different rows in weather
, the observational units have changed.
It is important to note that group_by
doesn’t change the data frame. It sets meta-data (data about the data), specifically the group structure of the data. It is only after we apply the summarize
function that the data frame changes.
If we would like to remove this group structure meta-data, we can pipe the resulting data frame into the ungroup()
function. For example, say the group structure meta-data is set to be by month via group_by(month)
, all future summarizations will be reported on a month-by-month basis. If however, we would like to no longer have this and have all summarizations be for all data in a single group (in this case over the entire year of 2013), then pipe the data frame in question through and ungroup()
to remove this.
We now revisit the n()
counting summary function we introduced in the previous section. For example, suppose we’d like to get a sense for how many flights departed each of the three airports in New York City:
by_origin <- flights %>%
group_by(origin) %>%
summarize(count = n())
kable(by_origin)
origin | count |
---|---|
EWR | 120835 |
JFK | 111279 |
LGA | 104662 |
We see that Newark ("EWR"
) had the most flights departing in 2013 followed by "JFK"
and lastly by LaGuardia ("LGA"
). Note there is a subtle but important difference between sum()
and n()
. While sum()
simply adds up a large set of numbers, the latter counts the number of times each of many different values occur.
You are not limited to grouping by one variable! Say you wanted to know the number of flights leaving each of the three New York City airports for each month, we can also group by a second variable month
: group_by(origin, month)
.
by_monthly_origin <- flights %>%
group_by(origin, month) %>%
summarize(count = n())
kable(by_monthly_origin)
origin | month | count |
---|---|---|
EWR | 1 | 9893 |
EWR | 2 | 9107 |
EWR | 3 | 10420 |
EWR | 4 | 10531 |
EWR | 5 | 10592 |
EWR | 6 | 10175 |
EWR | 7 | 10475 |
EWR | 8 | 10359 |
EWR | 9 | 9550 |
EWR | 10 | 10104 |
EWR | 11 | 9707 |
EWR | 12 | 9922 |
JFK | 1 | 9161 |
JFK | 2 | 8421 |
JFK | 3 | 9697 |
JFK | 4 | 9218 |
JFK | 5 | 9397 |
JFK | 6 | 9472 |
JFK | 7 | 10023 |
JFK | 8 | 9983 |
JFK | 9 | 8908 |
JFK | 10 | 9143 |
JFK | 11 | 8710 |
JFK | 12 | 9146 |
LGA | 1 | 7950 |
LGA | 2 | 7423 |
LGA | 3 | 8717 |
LGA | 4 | 8581 |
LGA | 5 | 8807 |
LGA | 6 | 8596 |
LGA | 7 | 8927 |
LGA | 8 | 8985 |
LGA | 9 | 9116 |
LGA | 10 | 9642 |
LGA | 11 | 8851 |
LGA | 12 | 9067 |
Alternatively, you can use the shortcut count()
function in dplyr
to get the same result:
by_monthly_origin2 <- flights %>%
dplyr::count(origin, month)
kable(by_monthly_origin2)
origin | month | n |
---|---|---|
EWR | 1 | 9893 |
EWR | 2 | 9107 |
EWR | 3 | 10420 |
EWR | 4 | 10531 |
EWR | 5 | 10592 |
EWR | 6 | 10175 |
EWR | 7 | 10475 |
EWR | 8 | 10359 |
EWR | 9 | 9550 |
EWR | 10 | 10104 |
EWR | 11 | 9707 |
EWR | 12 | 9922 |
JFK | 1 | 9161 |
JFK | 2 | 8421 |
JFK | 3 | 9697 |
JFK | 4 | 9218 |
JFK | 5 | 9397 |
JFK | 6 | 9472 |
JFK | 7 | 10023 |
JFK | 8 | 9983 |
JFK | 9 | 8908 |
JFK | 10 | 9143 |
JFK | 11 | 8710 |
JFK | 12 | 9146 |
LGA | 1 | 7950 |
LGA | 2 | 7423 |
LGA | 3 | 8717 |
LGA | 4 | 8581 |
LGA | 5 | 8807 |
LGA | 6 | 8596 |
LGA | 7 | 8927 |
LGA | 8 | 8985 |
LGA | 9 | 9116 |
LGA | 10 | 9642 |
LGA | 11 | 8851 |
LGA | 12 | 9067 |
Learning check
(LC5.5) Recall from Chapter 3 when we looked at plots of temperatures by months in NYC. What does the standard deviation column in the summary_monthly_temp
data frame tell us about temperatures in New York City throughout the year?
(LC5.6) What code would be required to get the mean and standard deviation temperature for each day in 2013 for NYC?
(LC5.7) Recreate by_monthly_origin
, but instead of grouping via group_by(origin, month)
, group variables in a different order group_by(month, origin)
. What differs in the resulting dataset?
(LC5.8) How could we identify how many flights left each of the three airports for each carrier
?
(LC5.9) How does the filter
operation differ from a group_by
followed by a summarize
?
5.2.4 5MV#4: Create new variables/change old variables using mutate
When looking at the flights
dataset, there are some clear additional variables that could be calculated based on the values of variables already in the dataset. Passengers are often frustrated when their flights departs late, but change their mood a bit if pilots can make up some time during the flight to get them to their destination close to when they expected to land. This is commonly referred to as “gain” and we will create this variable using the mutate
function. Note that we have also overwritten the flights
data frame with what it was before as well as an additional variable gain
here, or put differently, the mutate()
command outputs a new data frame which then gets saved over the original flights
data frame.
flights <- flights %>%
mutate(gain = dep_delay - arr_delay)
Why did we overwrite flights
instead of assigning the resulting data frame to a new object, like flights_with_gain
? As a rough rule of thumb, as long as you are not losing information that you might need later, it’s acceptable practice to overwrite data frames. However, if you overwrite existing variables and/or change the observational units, recovering the original information might prove difficult. In this case, it might make sense to create a new data object.
Let’s look at summary measures of this gain
variable and even plot it in the form of a histogram:
gain_summary <- flights %>%
summarize(
min = min(gain, na.rm = TRUE),
q1 = quantile(gain, 0.25, na.rm = TRUE),
median = quantile(gain, 0.5, na.rm = TRUE),
q3 = quantile(gain, 0.75, na.rm = TRUE),
max = max(gain, na.rm = TRUE),
mean = mean(gain, na.rm = TRUE),
sd = sd(gain, na.rm = TRUE),
missing = sum(is.na(gain))
)
kable(gain_summary)
min | q1 | median | q3 | max | mean | sd | missing |
---|---|---|---|---|---|---|---|
-196 | -3 | 7 | 17 | 109 | 5.66 | 18.04 | 9430 |
We’ve recreated the summary
function we saw in Chapter 3 here using the summarize
function in dplyr
.
ggplot(data = flights, mapping = aes(x = gain)) +
geom_histogram(color = "white", bins = 20)
We can also create multiple columns at once and even refer to columns that were just created in a new column. Hadley and Garrett produce one such example in Chapter 5 of “R for Data Science” (Grolemund and Wickham 2016):
flights <- flights %>%
mutate(
gain = dep_delay - arr_delay,
hours = air_time / 60,
gain_per_hour = gain / hours
)
Learning check
(LC5.10) What do positive values of the gain
variable in flights
correspond to? What about negative values? And what about a zero value?
(LC5.11) Could we create the dep_delay
and arr_delay
columns by simply subtracting dep_time
from sched_dep_time
and similarly for arrivals? Try the code out and explain any differences between the result and what actually appears in flights
.
(LC5.12) What can we say about the distribution of gain
? Describe it in a few sentences using the plot and the gain_summary
data frame values.
5.2.5 5MV#5: Reorder the data frame using arrange
One of the most common things people working with data would like to do is sort the data frames by a specific variable in a column. Have you ever been asked to calculate a median by hand? This requires you to put the data in order from smallest to highest in value. The dplyr
package has a function called arrange
that we will use to sort/reorder our data according to the values of the specified variable. This is often used after we have used the group_by
and summarize
functions as we will see.
Let’s suppose we were interested in determining the most frequent destination airports from New York City in 2013:
freq_dest <- flights %>%
group_by(dest) %>%
summarize(num_flights = n())
freq_dest
# A tibble: 105 x 2
dest num_flights
<chr> <int>
1 ABQ 254
2 ACK 265
3 ALB 439
4 ANC 8
5 ATL 17215
6 AUS 2439
7 AVL 275
8 BDL 443
9 BGR 375
10 BHM 297
# ... with 95 more rows
You’ll see that by default the values of dest
are displayed in alphabetical order here. We are interested in finding those airports that appear most:
freq_dest %>% arrange(num_flights)
# A tibble: 105 x 2
dest num_flights
<chr> <int>
1 LEX 1
2 LGA 1
3 ANC 8
4 SBN 10
5 HDN 15
6 MTJ 15
7 EYW 17
8 PSP 19
9 JAC 25
10 BZN 36
# ... with 95 more rows
This is actually giving us the opposite of what we are looking for. It tells us the least frequent destination airports first. To switch the ordering to be descending instead of ascending we use the desc
(desc
ending) function:
freq_dest %>% arrange(desc(num_flights))
# A tibble: 105 x 2
dest num_flights
<chr> <int>
1 ORD 17283
2 ATL 17215
3 LAX 16174
4 BOS 15508
5 MCO 14082
6 CLT 14064
7 SFO 13331
8 FLL 12055
9 MIA 11728
10 DCA 9705
# ... with 95 more rows
5.3 Joining data frames
Another common task is joining/merging two different datasets. For example, in the flights
data, the variable carrier
lists the carrier code for the different flights. While "UA"
and "AA"
might be somewhat easy to guess for some (United and American Airlines), what are “VX”, “HA”, and “B6”? This information is provided in a separate data frame airlines
.
View(airlines)
We see that in airports
, carrier
is the carrier code while name
is the full name of the airline. Using this table, we can see that “VX”, “HA”, and “B6” correspond to Virgin America, Hawaiian Airlines, and JetBlue respectively. However, will we have to continually look up the carrier’s name for each flight in the airlines
dataset? No! Instead of having to do this manually, we can have R automatically do the “looking up” for us.
Note that the values in the variable carrier
in flights
match the values in the variable carrier
in airlines
. In this case, we can use the variable carrier
as a key variable to join/merge/match the two data frames by. Hadley and Garrett (Grolemund and Wickham 2016) created the following diagram to help us understand how the different datasets are linked:
5.3.1 Joining by key variables
In both flights
and airlines
, the key variable we want to join/merge/match the two data frames with has the same name in both datasets: carriers
. We make use of the inner_join()
function to join by the variable carrier
.
flights_joined <- flights %>%
inner_join(airlines, by = "carrier")
View(flights)
View(flights_joined)
We observed that the flights
and flights_joined
are identical except that flights_joined
has an additional variable name
whose values were drawn from airlines
.
A visual representation of the inner_join
is given below (Grolemund and Wickham 2016):
There are more complex joins available, but the inner_join
will solve nearly all of the problems you’ll face in our experience.
5.3.2 Joining by key variables with different names
Say instead, you are interested in all the destinations of flights from NYC in 2013 and ask yourself:
- “What cities are these airports in?”
- “Is
"ORD"
Orlando?” - “Where is
"FLL"
?
The airports
data frame contains airport codes:
View(airports)
However, looking at both the airports
and flights
and the visual representation of the relations between the data frames in Figure 5.8, we see that in:
airports
the airport code is in the variablefaa
flights
the airport code is in the variableorigin
So to join these two datasets, our inner_join
operation involves a by
argument that accounts for the different names:
flights %>%
inner_join(airports, by = c("dest" = "faa"))
Let’s construct the sequence of commands that computes the number of flights from NYC to each destination, but also includes information about each destination airport:
named_dests <- flights %>%
group_by(dest) %>%
summarize(num_flights = n()) %>%
arrange(desc(num_flights)) %>%
inner_join(airports, by = c("dest" = "faa")) %>%
rename(airport_name = name)
View(named_dests)
In case you didn’t know, "ORD"
is the airport code of Chicago O’Hare airport and "FLL"
is the main airport in Fort Lauderdale, Florida, which we can now see in our named_freq_dests
data frame.
Learning check
(LC5.13) Looking at Figure 5.7, when joining flights
and weather
(or, in other words, matching the hourly weather values with each flight), why do we need to join by all of year
, month
, day
, hour
, and origin
, and not just hour
?
(LC5.14) What surprises you about the top 10 destinations from NYC in 2013?
5.4 Optional: Other verbs
On top of the following examples of other verbs, if you’d like to see more examples on using dplyr
, the 5MV, and %>%
with the nycflights13
dataset, check out Chapter 5 of Hadley and Garrett’s book (Grolemund and Wickham 2016).
5.4.1 Select variables using select
We’ve seen that the flights
data frame in the nycflights13
package contains many different variables. The names
function gives a listing of all the columns in a data frame; in our case you would run names(flights)
. You can also identify these variables by running the glimpse
function in the dplyr
package:
glimpse(flights)
However, say you only want to consider two of these variables, say carrier
and flight
. You can select
these:
flights %>%
select(carrier, flight)
Another one of these variables is year
. If you remember the original description of the flights
data frame (or by running ?flights
), you’ll remember that this data correspond to flights in 2013 departing New York City. The year
variable isn’t really a variable here in that it doesn’t vary… flights
actually comes from a larger dataset that covers many years. We may want to remove the year
variable from our dataset since it won’t be helpful for analysis in this case. We can deselect year
by using the -
sign:
flights_no_year <- flights %>%
select(-year)
names(flights_no_year)
Or we could specify a ranges of columns:
flight_arr_times <- flights %>%
select(month:day, arr_time:sched_arr_time)
flight_arr_times
The select
function can also be used to reorder columns in combination with the everything
helper function. Let’s suppose we’d like the hour
, minute
, and time_hour
variables, which appear at the end of the flights
dataset, to actually appear immediately after the day
variable:
flights_reorder <- flights %>%
select(month:day, hour:time_hour, everything())
names(flights_reorder)
in this case everything()
picks up all remaining variables. Lastly, the helper functions starts_with
, ends_with
, and contains
can be used to choose column names that match those conditions:
flights_begin_a <- flights %>%
select(starts_with("a"))
flights_begin_a
flights_delays <- flights %>%
select(ends_with("delay"))
flights_delays
flights_time <- flights %>%
select(contains("time"))
flights_time
5.4.2 Rename variables using rename
Another useful function is rename
, which as you may suspect renames one column to another name. Suppose we wanted dep_time
and arr_time
to be departure_time
and arrival_time
instead in the flights_time
data frame:
flights_time_new <- flights %>%
select(contains("time")) %>%
rename(departure_time = dep_time,
arrival_time = arr_time)
names(flights_time)
Note that in this case we used a single =
sign with the rename()
. Ex: departure_time = dep_time
. This is because we are not testing for equality like we would using ==
, but instead we want to assign a new variable departure_time
to have the same values as dep_time
and then delete the variable dep_time
.
It’s easy to forget if the new name comes before or after the equals sign. I usually remember this as “New Before, Old After” or NBOA. You’ll receive an error if you try to do it the other way:
Error: Unknown variables: departure_time, arrival_time.
5.4.3 Find the top number of values using top_n
We can also use the top_n
function which automatically tells us the most frequent num_flights
. We specify the top 10 airports here:
named_dests %>%
top_n(n = 10, wt = num_flights)
We’ll still need to arrange this by num_flights
though:
named_dests %>%
top_n(n = 10, wt = num_flights) %>%
arrange(desc(num_flights))
Note: Remember that I didn’t pull the n
and wt
arguments out of thin air. They can be found by using the ?
function on top_n
.
We can go one stop further and tie together the group_by
and summarize
functions we used to find the most frequent flights:
ten_freq_dests <- flights %>%
group_by(dest) %>%
summarize(num_flights = n()) %>%
arrange(desc(num_flights)) %>%
top_n(n = 10)
View(ten_freq_dests)
Learning check
(LC5.15) What are some ways to select all three of the dest
, air_time
, and distance
variables from flights
? Give the code showing how to do this in at least three different ways.
(LC5.16) How could one use starts_with
, ends_with
, and contains
to select columns from the flights
data frame? Provide three different examples in total: one for starts_with
, one for ends_with
, and one for contains
.
(LC5.17) Why might we want to use the select
function on a data frame?
(LC5.18) Create a new data frame that shows the top 5 airports with the largest arrival delays from NYC in 2013.
5.5 Conclusion
5.5.1 Review questions
Review questions have been designed using the fivethirtyeight
R package (Kim, Ismay, and Chunn 2017) with links to the corresponding FiveThirtyEight.com articles in our free DataCamp course Effective Data Storytelling using the tidyverse
. The material in this chapter is covered in the chapters of the DataCamp course available below:
5.5.2 What’s to come?
We will see in Chapter 6 many of the same ideas we have seen with hypothesis testing and confidence intervals in the last two chapters. Regression is frequently associated both correctly and incorrectly with statistics and data analysis, so you’ll need to make sure you understand when it is appropriate and when it is not.
5.5.3 Resources
As we saw with the RStudio cheatsheet on data visualization, RStudio has also created a cheatsheet for data wrangling entitled “Data Transformation with dplyr”.
5.5.4 Script of R code
An R script file of all R code used in this chapter is available here.