> Visualize data
### Filter data
Use the `Filter data` box to select (or omit) specific sets of rows from the data. See the help file for _Data > View_ for details.
### Plot-type
Select the plot type you want. For example, with the `diamonds` data loaded select `Distribution` and all (X) variables (use CTRL-a or CMD-a). This will create a histogram for all numeric variables and a bar-plot for all categorical variables in the data set. Density plots can only be used with numeric variables. Scatter plots are used to visualize the relationship between two variables. Select one or more variables to plot on the Y-axis and one or more variables to plot on the X-axis. If one of the variables is categorical (i.e., a {factor}) it should be specified as an X-variable. Information about additional variables can be added through the `Color` or `Size` dropdown. Line plots are similar to scatter plots but they connect-the-dots and are particularly useful for time-series data. Surface plots are similar to `Heat maps` and require 3 input variables: X, Y, and Fill. Bar plots are used to show the relationship between a categorical (or integer) variable (X) and the (mean) value of a numeric variable (Y). Box-plots are also used when we have a numeric Y-variable and a categorical X-variable. They are more informative than bar charts but also require a bit more effort to evaluate.
> Note that when a categorical variable (`factor`) is selected as the `Y-variable` in a Bar chart it will be converted to a numeric variable if required for the selected function. If the factor levels are numeric these will be used in all calculations. Since the mean, standard deviation, etc. are not relevant for non-binary categorical variables, these will be converted to 0-1 (binary) variables where the first level is coded as 1 and all other levels as 0. For example, if we select `color` from the `diamonds` data as the Y-variable, and `mean` as the function to apply, then each bar will represent the proportion of observations with the value `D`.
### Box plots
The upper and lower "hinges" of the box correspond to the first and third quartiles (the 25th and 75th percentiles) in the data. The middle hinge is the median value of the data. The upper whisker extends from the upper hinge (i.e., the top of the box) to the highest value in the data that is within 1.5 x IQR of the upper hinge. IQR is the inter-quartile range, or distance, between the 25th and 75th percentile. The lower whisker extends from the lower hinge to the lowest value in the data within 1.5 x IQR of the lower hinge. Data beyond the end of the whiskers could be outliers and are plotted as points (as suggested by Tukey).
In sum:
1. The lower whisker extends from Q1 to max(min(data), Q1 - 1.5 x IQR)
2. The upper whisker extends from Q3 to min(max(data), Q3 + 1.5 x IQR)
where Q1 is the 25th percentile and Q3 is the 75th percentile. You may have to read the two bullets above a few times before it sinks in. The plot below should help to explain the structure of the box plot.
Source
### Sub-plots and heat-maps
`Facet row` and `Facet column` can be used to split the data into different groups and create separate plots for each group.
If you select a scatter or line plot a `Color` drop-down will be shown. Selecting a `Color` variable will create a type of heat-map where the colors are linked to the values of the `Color` variable. Selecting a categorical variable from the `Color` dropdown for a line plot will split the data into groups and will show a line of a different color for each group.
### Line, loess, and jitter
To add a linear or non-linear regression line to a scatter plot check the `Line` and/or `Loess` boxes. If your data take on a limited number of values, `Jitter` can be useful to get a better feel for where most of the data points are located. `Jitter`-ing simply adds a small random value to each data point so they do not overlap completely in the plot(s).
### Axis scale
The relationship between variables depicted in a scatter plot may be non-linear. There are numerous transformations we might apply to the data so this relationship becomes (approximately) linear (see _Data > Transform_) and easier to estimate using, for example, _Model > Estimate > Linear regression (OLS)_. Perhaps the most common data transformation applied to business data is the (natural) logarithm. To see if log transformation(s) may be appropriate for your data check the `Log X` and/or `Log Y` boxes (e.g., for a scatter or bar plot).
By default the scale of the Y-axis is the same across sub-plots when using `Facet row`. To allow the Y-axis to be specific to each sub-plot click the `Scale-y` check-box.
### Flip axes
To switch the variables on the X- and Y-axis check the `Flip` box.
### Plot height and width
To make plots bigger or smaller adjust the values in the height and width boxes on the bottom left of the screen.
### Keep plots
The best way to keep/store plots is to generate a `visualize` command by clicking the report () icon on the bottom left of your screen or by pressing `ALT-enter` on your keyboard. Alternatively, click the icon on the top right of your screen to save a png-file to disk.
### Customizing plots in _Report > Rmd_
To customize a plot first generate the `visualize` command by clicking the report () icon on the bottom left of your screen or by pressing `ALT-enter` on your keyboard. The example below illustrates how to customize a command in the _Report > Rmd_ tab. Notice that `custom` is set to `TRUE`.
```r
visualize(diamonds, yvar = "price", xvar = "carat", type = "scatter", custom = TRUE) +
labs(
title = "A scatterplot",
y = "Price in $",
x = "Carats"
)
```
The default resolution for plots is 144 dots per inch (dpi). You can change this setting up or down in _Report > Rmd_. For example, the code-chunk header below ensures the plot will be 7" wide, 3.5" tall, with a resolution of 600 dpi.
```` ```{r fig.width = 7, fig.height = 3.5, dpi = 600} ````
If you have the `svglite` package installed, the code-chunk header below will produce graphs in high quality `svg` format.
```` ```{r fig.width = 7, fig.height = 3.5, dev = "svglite"} ````
**Some common customization commands:**
* Add a title: `+ labs(title = "my title")`
* Add a sub-title: `+ labs(subtitle = "my sub-title")`
* Add a caption below figure: `+ labs(caption = "Based on data from ...")`
* Change label: `+ labs(x = "my X-axis label")` or `+ labs(y = "my Y-axis label")`
* Remove all legends: `+ theme(legend.position = "none")`
* Change legend title: `+ labs(color = "New legend title")` or `+ labs(fill = "New legend title")`
* Rotate tick labels: `+ theme(axis.text.x = element_text(angle = 90, hjust = 1))`
* Set plot limits: `+ ylim(5000, 8000)` or `+ xlim("VS1","VS2")`
* Remove size legend: `+ scale_size(guide = "none")`
* Change size range: `+ scale_size(range=c(1,6))`
* Draw a horizontal line: `+ geom_hline(yintercept = 0.1)`
* Draw a vertical line: `+ geom_vline(xintercept = 8)`
* Scale the y-axis as a percentage: `+ scale_y_continuous(labels = scales::percent)`
* Scale the y-axis in millions: `+ scale_y_continuous(labels = scales::unit_format(unit = "M", scale = 1e-6))`
* Display y-axis in \$'s: `+ scale_y_continuous(labels = scales::dollar_format())`
* Use `,` as a thousand separator for the y-axis: `+ scale_y_continuous(labels = scales::comma)`
For more on how to customize plots for communication see http://r4ds.had.co.nz/graphics-for-communication.html.
See also the ggplot2 documentation site https://ggplot2.tidyverse.org.
Suppose we create a set of three bar charts in _Data > Visualize_ using the `Diamond` data. To add a title above the group of plots and impose a one-column layout we could use `patchwork` as follows:
```r
library(patchwork)
plot_list <- visualize(
diamonds,
xvar = c("clarity", "cut", "color"),
yvar = "price",
type = "bar",
custom = TRUE
)
wrap_plots(plot_list, ncol = 1) + plot_annotation(title = "Three bar plots")
```
See the patchwork documentation site for additional information on how to customize groups of plots.
### Making plots interactive in _Report > Rmd_
It is possible to transform (most) plots generated in Radiant into interactive graphics using the `plotly` library. After setting `custom = TRUE` you can use the `ggplotly` function to convert a single plot. See example below:
```r
visualize(diamonds, xvar = "price", custom = TRUE) %>%
ggplotly() %>%
render()
```
If more than one plot is created, you can use the `subplot` function from the `plotly` package. Provide a value for the `nrows` argument to setup the plot layout grid. In the example below four plots are created. Because `nrow = 2` the plots will be displayed in a 2 X 2 grid.
```r
visualize(diamonds, xvar = c("carat", "clarity", "cut", "color"), custom = TRUE) %>%
subplot(nrows = 2) %>%
render()
```
For additional information on the `plotly` library see the links below:
* Getting started: https://plot.ly/r/getting-started/
* Reference: https://plot.ly/r/reference/
* Book: https://cpsievert.github.io/plotly_book
* Code: https://github.com/ropensci/plotly
### R-functions
For an overview of related R-functions used by Radiant to visualize data see _Data > Visualize_