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correct ordered factor definition (#1686)
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Co-authored-by: Hadley Wickham <[email protected]>
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leorjorge and hadley authored Sep 27, 2024
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Expand Up @@ -56,7 +56,7 @@ To create a factor you must start by creating a list of the valid **levels**:

```{r}
month_levels <- c(
"Jan", "Feb", "Mar", "Apr", "May", "Jun",
"Jan", "Feb", "Mar", "Apr", "May", "Jun",
"Jul", "Aug", "Sep", "Oct", "Nov", "Dec"
)
```
Expand Down Expand Up @@ -169,7 +169,7 @@ relig_summary <- gss_cat |>
n = n()
)
ggplot(relig_summary, aes(x = tvhours, y = relig)) +
ggplot(relig_summary, aes(x = tvhours, y = relig)) +
geom_point()
```

Expand Down Expand Up @@ -212,7 +212,7 @@ What if we create a similar plot looking at how average age varies across report
#| fig-alt: |
#| A scatterplot with age on the x-axis and income on the y-axis. Income
#| has been reordered in order of average age which doesn't make much
#| sense. One section of the y-axis goes from $6000-6999, then <$1000,
#| sense. One section of the y-axis goes from $6000-6999, then <$1000,
#| then $8000-9999.
rincome_summary <- gss_cat |>
group_by(rincome) |>
Expand All @@ -221,7 +221,7 @@ rincome_summary <- gss_cat |>
n = n()
)
ggplot(rincome_summary, aes(x = age, y = fct_reorder(rincome, age))) +
ggplot(rincome_summary, aes(x = age, y = fct_reorder(rincome, age))) +
geom_point()
```

Expand Down Expand Up @@ -257,29 +257,29 @@ This makes the plot easier to read because the colors of the line at the far rig
#| A line plot with age on the x-axis and proportion on the y-axis.
#| There is one line for each category of marital status: no answer,
#| never married, separated, divorced, widowed, and married. It is
#| a little hard to read the plot because the order of the legend is
#| unrelated to the lines on the plot. Rearranging the legend makes
#| the plot easier to read because the legend colors now match the
#| order of the lines on the far right of the plot. You can see some
#| unsurprising patterns: the proportion never married decreases with
#| age, married forms an upside down U shape, and widowed starts off
#| a little hard to read the plot because the order of the legend is
#| unrelated to the lines on the plot. Rearranging the legend makes
#| the plot easier to read because the legend colors now match the
#| order of the lines on the far right of the plot. You can see some
#| unsurprising patterns: the proportion never married decreases with
#| age, married forms an upside down U shape, and widowed starts off
#| low but increases steeply after age 60.
by_age <- gss_cat |>
filter(!is.na(age)) |>
filter(!is.na(age)) |>
count(age, marital) |>
group_by(age) |>
mutate(
prop = n / sum(n)
)
ggplot(by_age, aes(x = age, y = prop, color = marital)) +
geom_line(linewidth = 1) +
geom_line(linewidth = 1) +
scale_color_brewer(palette = "Set1")
ggplot(by_age, aes(x = age, y = prop, color = fct_reorder2(marital, age, prop))) +
geom_line(linewidth = 1) +
scale_color_brewer(palette = "Set1") +
labs(color = "marital")
scale_color_brewer(palette = "Set1") +
labs(color = "marital")
```

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.
Expand All @@ -288,7 +288,7 @@ Combine it with `fct_rev()` if you want them in increasing frequency so that in
```{r}
#| fig-alt: |
#| A bar char of marital status ordered from least to most common:
#| no answer (~0), separated (~1,000), widowed (~2,000), divorced
#| no answer (~0), separated (~1,000), widowed (~2,000), divorced
#| (~3,000), never married (~5,000), married (~10,000).
gss_cat |>
mutate(marital = marital |> fct_infreq() |> fct_rev()) |>
Expand Down Expand Up @@ -409,21 +409,24 @@ Read the documentation to learn about `fct_lump_min()` and `fct_lump_prop()` whi

## Ordered factors {#sec-ordered-factors}

Before we go on, there's a special type of factor that needs to be mentioned briefly: ordered factors.
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.
You can recognize them when printing because they use `<` between the factor levels:
Before we continue, it's important to briefly mention a special type of factor: ordered factors.
Created with the `ordered()` function, ordered factors imply a strict ordering between levels, but don't specify anything about the magnitude of the differences between the levels.
You use ordered factors when you know there the levels are ranked, but there's no precise numerical ranking.

You can identify an ordered factor when its printed because it uses `<` symbols between the factor levels:

```{r}
ordered(c("a", "b", "c"))
```

In practice, `ordered()` factors behave very similarly to regular factors.
In both base R and the tidyverse, ordered factors behave very similarly to regular factors.
There are only two places where you might notice different behavior:

- 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.
- 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.
- If you use an ordered predictor in a linear model, it will use "polynomial 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.

Given the arguable utility of these differences, we don't generally recommend using ordered factors.
For the purposes of this book, correctly distinguishing between regular and ordered factors is not particularly important.
More broadly, however, certain fields (particularly the social sciences) do use ordered factors extensively.
In these contexts, it's important to correctly identify them so that other analysis packages can offer the appropriate behavior.

## Summary

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