442 lines
16 KiB
Plaintext
442 lines
16 KiB
Plaintext
# Factors {#sec-factors}
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```{r}
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#| results: "asis"
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#| echo: false
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source("_common.R")
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status("complete")
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```
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## Introduction
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Factors are used for categorical variables, variables that have a fixed and known set of possible values.
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They are also useful when you want to display character vectors in a non-alphabetical order.
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We'll start by motivating why factors are needed for data analysis[^factors-1] and how you can create them with `factor()`. We'll then introduce you to the `gss_cat` dataset which contains a bunch of categorical variables to experiment with.
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You'll then use that dataset to practice modifying the order and values of factors, before we finish up with a discussion of ordered factors.
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[^factors-1]: They're also really important for modelling.
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### Prerequisites
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Base R provides some basic tools for creating and manipulating factors.
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We'll supplement these with the **forcats** package, which is part of the core tidyverse.
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It provides tools for dealing with **cat**egorical variables (and it's an anagram of factors!) using a wide range of helpers for working with factors.
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```{r}
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#| label: setup
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#| message: false
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library(tidyverse)
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```
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## Factor basics
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Imagine that you have a variable that records month:
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```{r}
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x1 <- c("Dec", "Apr", "Jan", "Mar")
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```
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Using a string to record this variable has two problems:
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1. There are only twelve possible months, and there's nothing saving you from typos:
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```{r}
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x2 <- c("Dec", "Apr", "Jam", "Mar")
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```
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2. It doesn't sort in a useful way:
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```{r}
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sort(x1)
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```
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You can fix both of these problems with a factor.
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To create a factor you must start by creating a list of the valid **levels**:
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```{r}
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month_levels <- c(
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"Jan", "Feb", "Mar", "Apr", "May", "Jun",
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"Jul", "Aug", "Sep", "Oct", "Nov", "Dec"
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)
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```
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Now you can create a factor:
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```{r}
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y1 <- factor(x1, levels = month_levels)
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y1
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sort(y1)
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```
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And any values not in the level will be silently converted to NA:
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```{r}
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y2 <- factor(x2, levels = month_levels)
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y2
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```
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This seems risky, so you might want to use `forcats::fct()` instead:
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```{r}
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#| error: true
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y2 <- fct(x2, levels = month_levels)
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```
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If you omit the levels, they'll be taken from the data in alphabetical order:
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```{r}
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factor(x1)
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```
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Sorting alphabetically is slightly risky because not every computer will sort strings in the same way.
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So `forcats::fct()` orders by first appearance:
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```{r}
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fct(x1)
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```
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If you ever need to access the set of valid levels directly, you can do so with `levels()`:
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```{r}
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levels(y2)
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```
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You can also create a factor when reading your data with readr with `col_factor()`:
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```{r}
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csv <- "
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month,value
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Jan,12
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Feb,56
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Mar,12"
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df <- read_csv(csv, col_types = cols(month = col_factor(month_levels)))
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df$month
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```
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## General Social Survey
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For the rest of this chapter, we're going to use `forcats::gss_cat`.
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It's a sample of data from the [General Social Survey](https://gss.norc.org), a long-running US survey conducted by the independent research organization NORC at the University of Chicago.
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The survey has thousands of questions, so in `gss_cat` Hadley selected a handful that will illustrate some common challenges you'll encounter when working with factors.
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```{r}
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gss_cat
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```
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(Remember, since this dataset is provided by a package, you can get more information about the variables with `?gss_cat`.)
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When factors are stored in a tibble, you can't see their levels so easily.
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One way to view them is with `count()`:
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```{r}
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gss_cat |>
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count(race)
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```
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When working with factors, the two most common operations are changing the order of the levels, and changing the values of the levels.
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Those operations are described in the sections below.
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### Exercise
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1. Explore the distribution of `rincome` (reported income).
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What makes the default bar chart hard to understand?
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How could you improve the plot?
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2. What is the most common `relig` in this survey?
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What's the most common `partyid`?
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3. Which `relig` does `denom` (denomination) apply to?
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How can you find out with a table?
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How can you find out with a visualization?
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## Modifying factor order {#sec-modifying-factor-order}
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It's often useful to change the order of the factor levels in a visualization.
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For example, imagine you want to explore the average number of hours spent watching TV per day across religions:
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```{r}
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#| fig-alt: >
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#| A scatterplot of with tvhours on the x-axis and religion on the y-axis.
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#| The y-axis is ordered seemingly aribtrarily making it hard to get
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#| any sense of overall pattern.
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relig_summary <- gss_cat |>
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group_by(relig) |>
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summarize(
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tvhours = mean(tvhours, na.rm = TRUE),
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n = n()
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)
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ggplot(relig_summary, aes(x = tvhours, y = relig)) +
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geom_point()
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```
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It is hard to read this plot because there's no overall pattern.
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We can improve it by reordering the levels of `relig` using `fct_reorder()`.
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`fct_reorder()` takes three arguments:
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- `f`, the factor whose levels you want to modify.
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- `x`, a numeric vector that you want to use to reorder the levels.
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- Optionally, `fun`, a function that's used if there are multiple values of `x` for each value of `f`. The default value is `median`.
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```{r}
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#| fig-alt: >
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#| The same scatterplot as above, but now the religion is displayed in
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#| increasing order of tvhours. "Other eastern" has the fewest tvhours
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#| under 2, and "Don't know" has the highest (over 5).
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ggplot(relig_summary, aes(x = tvhours, y = fct_reorder(relig, tvhours))) +
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geom_point()
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```
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Reordering religion makes it much easier to see that people in the "Don't know" category watch much more TV, and Hinduism & Other Eastern religions watch much less.
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As you start making more complicated transformations, we recommend moving them out of `aes()` and into a separate `mutate()` step.
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For example, you could rewrite the plot above as:
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```{r}
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#| eval: false
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relig_summary |>
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mutate(
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relig = fct_reorder(relig, tvhours)
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) |>
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ggplot(aes(x = tvhours, y = relig)) +
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geom_point()
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```
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What if we create a similar plot looking at how average age varies across reported income level?
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```{r}
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#| fig-alt: >
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#| A scatterplot with age on the x-axis and income on the y-axis. Income
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#| has been reordered in order of average age which doesn't make much
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#| sense. One section of the y-axis goes from $6000-6999, then <$1000,
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#| then $8000-9999.
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rincome_summary <- gss_cat |>
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group_by(rincome) |>
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summarize(
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age = mean(age, na.rm = TRUE),
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n = n()
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)
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ggplot(rincome_summary, aes(x = age, y = fct_reorder(rincome, age))) +
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geom_point()
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```
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Here, arbitrarily reordering the levels isn't a good idea!
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That's because `rincome` already has a principled order that we shouldn't mess with.
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Reserve `fct_reorder()` for factors whose levels are arbitrarily ordered.
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However, it does make sense to pull "Not applicable" to the front with the other special levels.
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You can use `fct_relevel()`.
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It takes a factor, `f`, and then any number of levels that you want to move to the front of the line.
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```{r}
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#| fig-alt: >
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#| The same scatterplot but now "Not Applicable" is displayed at the
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#| bottom of the y-axis. Generally there is a positive association
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#| between income and age, and the income band with the highethst average
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#| age is "Not applicable".
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ggplot(rincome_summary, aes(x = age, y = fct_relevel(rincome, "Not applicable"))) +
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geom_point()
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```
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Why do you think the average age for "Not applicable" is so high?
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Another type of reordering is useful when you are coloring the lines on a plot.
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`fct_reorder2(f, x, y)` reorders the factor `f` by the `y` values associated with the largest `x` values.
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This makes the plot easier to read because the colors of the line at the far right of the plot will line up with the legend.
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```{r}
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#| layout-ncol: 2
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#| fig-width: 3
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#| fig-alt: >
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#| A line plot with age on the x-axis and proportion on the y-axis.
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#| There is one line for each category of marital status: no answer,
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#| never married, separated, divorced, widowed, and married. It is
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#| a little hard to read the plot because the order of the legend is
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#| unrelated to the lines on the plot.
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#|
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#| Rearranging the legend makes the plot easier to read because the
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#| legend colors now match the order of the lines on the far right
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#| of the plot. You can see some unsurprising patterns: the proportion
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#| never married decreases with age, married forms an upside down U
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#| shape, and widowed starts off low but increases steeply after age
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#| 60.
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by_age <- gss_cat |>
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filter(!is.na(age)) |>
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count(age, marital) |>
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group_by(age) |>
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mutate(
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prop = n / sum(n)
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)
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ggplot(by_age, aes(x = age, y = prop, color = marital)) +
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geom_line(linewidth = 1) +
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scale_color_brewer(palette = "Set1")
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ggplot(by_age, aes(x = age, y = prop, color = fct_reorder2(marital, age, prop))) +
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geom_line(linewidth = 1) +
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scale_color_brewer(palette = "Set1") +
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labs(color = "marital")
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```
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Finally, for bar plots, you can use `fct_infreq()` to order levels in decreasing frequency: this is the simplest type of reordering because it doesn't need any extra variables.
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Combine it with `fct_rev()` if you want them in increasing frequency so that in the bar plot largest values are on the right, not the left.
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```{r}
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#| fig-alt: >
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#| A bar char of marital status ordered in from least to most common:
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#| no answer (~0), separated (~1,000), widowed (~2,000), divorced
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#| (~3,000), never married (~5,000), married (~10,000).
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gss_cat |>
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mutate(marital = marital |> fct_infreq() |> fct_rev()) |>
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ggplot(aes(x = marital)) +
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geom_bar()
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```
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### Exercises
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1. There are some suspiciously high numbers in `tvhours`.
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Is the mean a good summary?
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2. For each factor in `gss_cat` identify whether the order of the levels is arbitrary or principled.
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3. Why did moving "Not applicable" to the front of the levels move it to the bottom of the plot?
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## Modifying factor levels
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More powerful than changing the orders of the levels is changing their values.
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This allows you to clarify labels for publication, and collapse levels for high-level displays.
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The most general and powerful tool is `fct_recode()`.
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It allows you to recode, or change, the value of each level.
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For example, take the `partyid` variable from the `gss_cat` data frame:
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```{r}
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gss_cat |> count(partyid)
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```
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The levels are terse and inconsistent.
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Let's tweak them to be longer and use a parallel construction.
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Like most rename and recoding functions in the tidyverse, the new values go on the left and the old values go on the right:
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```{r}
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gss_cat |>
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mutate(
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partyid = fct_recode(partyid,
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"Republican, strong" = "Strong republican",
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"Republican, weak" = "Not str republican",
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"Independent, near rep" = "Ind,near rep",
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"Independent, near dem" = "Ind,near dem",
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"Democrat, weak" = "Not str democrat",
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"Democrat, strong" = "Strong democrat"
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)
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) |>
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count(partyid)
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```
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`fct_recode()` will leave the levels that aren't explicitly mentioned as is, and will warn you if you accidentally refer to a level that doesn't exist.
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To combine groups, you can assign multiple old levels to the same new level:
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```{r}
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#| results: false
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gss_cat |>
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mutate(
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partyid = fct_recode(partyid,
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"Republican, strong" = "Strong republican",
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"Republican, weak" = "Not str republican",
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"Independent, near rep" = "Ind,near rep",
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"Independent, near dem" = "Ind,near dem",
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"Democrat, weak" = "Not str democrat",
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"Democrat, strong" = "Strong democrat",
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"Other" = "No answer",
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"Other" = "Don't know",
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"Other" = "Other party"
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)
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)
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```
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Use this technique with care: if you group together categories that are truly different you will end up with misleading results.
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If you want to collapse a lot of levels, `fct_collapse()` is a useful variant of `fct_recode()`.
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For each new variable, you can provide a vector of old levels:
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```{r}
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gss_cat |>
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mutate(
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partyid = fct_collapse(partyid,
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"other" = c("No answer", "Don't know", "Other party"),
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"rep" = c("Strong republican", "Not str republican"),
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"ind" = c("Ind,near rep", "Independent", "Ind,near dem"),
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"dem" = c("Not str democrat", "Strong democrat")
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)
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) |>
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count(partyid)
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```
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Sometimes you just want to lump together the small groups to make a plot or table simpler.
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That's the job of the `fct_lump_*()` family of functions.
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`fct_lump_lowfreq()` is a simple starting point that progressively lumps the smallest groups categories into "Other", always keeping "Other" as the smallest category.
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```{r}
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gss_cat |>
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mutate(relig = fct_lump_lowfreq(relig)) |>
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count(relig)
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```
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In this case it's not very helpful: it is true that the majority of Americans in this survey are Protestant, but we'd probably like to see some more details!
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Instead, we can use the `fct_lump_n()` to specify that we want exactly 10 groups:
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```{r}
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gss_cat |>
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mutate(relig = fct_lump_n(relig, n = 10)) |>
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count(relig, sort = TRUE)
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```
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Read the documentation to learn about `fct_lump_min()` and `fct_lump_prop()` which are useful in other cases.
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### Exercises
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1. How have the proportions of people identifying as Democrat, Republican, and Independent changed over time?
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2. How could you collapse `rincome` into a small set of categories?
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3. Notice there are 9 groups (excluding other) in the `fct_lump` example above.
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Why not 10?
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(Hint: type `?fct_lump`, and find the default for the argument `other_level` is "Other".)
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## Ordered factors {#sec-ordered-factors}
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Before we go on, there's a special type of factor that needs to be mentioned briefly: ordered factors.
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Ordered factors, created with `ordered()`, imply a strict ordering and equal distance between levels: the first level is "less than" the second level by the same amount that the second level is "less than" the third level, and so on.
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You can recognize them when printing because they use `<` between the factor levels:
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```{r}
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ordered(c("a", "b", "c"))
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```
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In practice, `ordered()` factors behave very similarly to regular factors.
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There are only two places where you might notice different behavior:
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- If you map an ordered factor to color or fill in ggplot2, it will default to `scale_color_viridis()`/`scale_fill_viridis()`, a color scale that implies a ranking.
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- If you use an ordered function in a linear model, it will use "polygonal contrasts". These are mildly useful, but you are unlikely to have heard of them unless you have a PhD in Statistics, and even then you probably don't routinely interpret them. If you want to learn more, we recommend `vignette("contrasts", package = "faux")` by Lisa DeBruine.
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Given the arguable utility of these differences, we don't generally recommend using ordered factors.
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## Summary
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This chapter introduced you to the handy forcats package for working with factors, introducing you to the most commonly used functions.
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forcats contains a wide range of other helpers that we didn't have space to discuss here, so whenever you're facing a factor analysis challenge that you haven't encountered before, I highly recommend skimming the [reference index](https://forcats.tidyverse.org/reference/index.html) to see if there's a canned function that can help solve your problem.
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If you want to learn more about factors after reading this chapter, we recommend reading Amelia McNamara and Nicholas Horton's paper, [*Wrangling categorical data in R*](https://peerj.com/preprints/3163/).
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This paper lays out some of the history discussed in [*stringsAsFactors: An unauthorized biography*](https://simplystatistics.org/posts/2015-07-24-stringsasfactors-an-unauthorized-biography/) and [*stringsAsFactors = \<sigh\>*](https://notstatschat.tumblr.com/post/124987394001/stringsasfactors-sigh), and compares the tidy approaches to categorical data outlined in this book with base R methods.
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An early version of the paper helped motivate and scope the forcats package; thanks Amelia & Nick!
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In the next chapter we'll switch gears to start learning about dates and times in R.
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Dates and times seem deceptively simple, but as you'll soon see, the more you learn about them, the more complex they seem to get!
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