In the following we’ll use the insight theme (3 others are available: billboard (default), graph and datalab) and ColorBrewer Set2 as default color palette.
Create barcharts with bb_barchart
:
library(billboarder)
# data
data("prod_par_filiere")
billboarder(data = prod_par_filiere) %>%
bb_barchart(
mapping = aes(x = annee, y = prod_hydraulique),
color = "#102246"
) %>%
bb_y_grid(show = TRUE) %>%
bb_y_axis(
tick = list(format = suffix("TWh")),
label = list(text = "production (in terawatt-hours)", position = "outer-top")
) %>%
bb_legend(show = FALSE) %>%
bb_labs(
title = "French hydraulic production",
caption = "Data source: RTE (https://opendata.reseaux-energies.fr/)"
)
To create a dodge barchart, if your data are in “wide” format, you
can use the following (otherwise you have to reshape your data in “long”
format, with tools such as pivot_longer
):
library(billboarder)
# data
data("prod_par_filiere")
billboarder() %>%
bb_barchart(
data = prod_par_filiere[, c("annee", "prod_hydraulique", "prod_eolien", "prod_solaire")]
) %>%
bb_data(
names = list(prod_hydraulique = "Hydraulic", prod_eolien = "Wind", prod_solaire = "Solar")
) %>%
bb_y_grid(show = TRUE) %>%
bb_y_axis(
tick = list(format = suffix("TWh")),
label = list(text = "production (in terawatt-hours)", position = "outer-top")
) %>%
bb_legend(position = "inset", inset = list(anchor = "top-right")) %>%
bb_labs(
title = "Renewable energy production",
caption = "Data source: RTE (https://opendata.reseaux-energies.fr/)"
)
Same principle for stacked bar charts :
library(billboarder)
# data
data("prod_par_filiere")
# stacked bar chart !
billboarder() %>%
bb_barchart(
data = prod_par_filiere[, c("annee", "prod_hydraulique", "prod_eolien", "prod_solaire")],
stacked = TRUE
) %>%
bb_data(
names = list(prod_hydraulique = "Hydraulic", prod_eolien = "Wind", prod_solaire = "Solar"),
labels = TRUE
) %>%
bb_colors_manual(
"prod_eolien" = "#41AB5D", "prod_hydraulique" = "#4292C6", "prod_solaire" = "#FEB24C"
) %>%
bb_y_grid(show = TRUE) %>%
bb_y_axis(
tick = list(format = suffix("TWh")),
label = list(text = "production (in terawatt-hours)", position = "outer-top")
) %>%
bb_legend(position = "inset", inset = list(anchor = "top-right")) %>%
bb_labs(
title = "Renewable energy production",
caption = "Data source: RTE (https://opendata.reseaux-energies.fr/)"
)
A classic one:
billboarder() %>%
bb_scatterplot(
data = mtcars,
x = "wt", y = "mpg", group = "cyl",
point_opacity = 1
) %>%
# don't display all values on x-axis
bb_axis(x = list(tick = list(fit = FALSE))) %>%
bb_point(r = 5) %>%
# add grids
bb_x_grid(show = TRUE) %>%
bb_y_grid(show = TRUE)
You can make a bubble chart using size
aes :
Create pie charts :
library(billboarder)
# data
data("prod_par_filiere")
nuclear2016 <- data.frame(
sources = c("Nuclear", "Other"),
production = c(
prod_par_filiere$prod_nucleaire[prod_par_filiere$annee == "2016"],
prod_par_filiere$prod_total[prod_par_filiere$annee == "2016"] -
prod_par_filiere$prod_nucleaire[prod_par_filiere$annee == "2016"]
)
)
# pie chart !
billboarder() %>%
bb_piechart(data = nuclear2016) %>%
bb_labs(
title = "Share of nuclear power in France in 2016",
caption = "Data source: RTE (https://opendata.reseaux-energies.fr/)"
)
You can also do donut charts :
billboarder() %>%
bb_donutchart(data = nuclear2016) %>%
bb_donut(
title = "Share of nuclear\nin France",
label = list(
format = JS("function(value, ratio, id) { return id + ': ' + d3.format('.0%')(ratio);}")
)
) %>%
bb_legend(show = FALSE) %>%
bb_labs(caption = "Data source: RTE (https://opendata.reseaux-energies.fr/)")
Date
(and a subchart)library(billboarder)
# data
data("equilibre_mensuel")
# line chart
billboarder() %>%
bb_linechart(
data = equilibre_mensuel[, c("date", "consommation", "production")],
type = "spline"
) %>%
bb_x_axis(tick = list(format = "%Y-%m", fit = FALSE)) %>%
bb_x_grid(show = TRUE) %>%
bb_y_grid(show = TRUE) %>%
bb_colors_manual("consommation" = "firebrick", "production" = "forestgreen") %>%
bb_legend(position = "right") %>%
bb_subchart(show = TRUE, size = list(height = 30)) %>%
bb_labs(
title = "Monthly electricity consumption and production in France (2007 - 2017)",
y = "In megawatt (MW)",
caption = "Data source: RTE (https://opendata.reseaux-energies.fr/)"
)
billboarder() %>%
bb_linechart(
data = equilibre_mensuel[, c("date", "consommation", "production")],
type = "spline"
) %>%
bb_x_axis(tick = list(format = "%Y-%m", fit = FALSE)) %>%
bb_x_grid(show = TRUE) %>%
bb_y_grid(show = TRUE) %>%
bb_colors_manual("consommation" = "firebrick", "production" = "forestgreen") %>%
bb_legend(position = "right") %>%
bb_zoom(
enabled = TRUE,
type = "drag",
resetButton = list(text = "Unzoom")
) %>%
bb_labs(
title = "Monthly electricity consumption and production in France (2007 - 2017)",
y = "In megawatt (MW)",
caption = "Data source: RTE (https://opendata.reseaux-energies.fr/)"
)
POSIXct
(and regions)library(billboarder)
# data
data("cdc_prod_filiere")
# Retrieve sunrise and and sunset data with `suncalc`
# library("suncalc")
# sun <- getSunlightTimes(date = as.Date("2017-06-12"), lat = 48.86, lon = 2.34, tz = "CET")
sun <- data.frame(
sunrise = as.POSIXct("2017-06-12 05:48:14"),
sunset = as.POSIXct("2017-06-12 21:55:32")
)
# line chart
billboarder() %>%
bb_linechart(
data = cdc_prod_filiere,
mapping = aes(date_heure, prod_solaire)
) %>%
bb_x_axis(tick = list(format = "%H:%M", fit = FALSE)) %>%
bb_y_axis(min = 0, padding = 0) %>%
bb_regions(
list(
start = as.numeric(cdc_prod_filiere$date_heure[1]) * 1000,
end = as.numeric(sun$sunrise)*1000
),
list(
start = as.numeric(sun$sunset) * 1000,
end = as.numeric(cdc_prod_filiere$date_heure[48]) * 1000
)
) %>%
bb_x_grid(
lines = list(
list(value = as.numeric(sun$sunrise)*1000, text = "sunrise"),
list(value = as.numeric(sun$sunset)*1000, text = "sunset")
)
) %>%
bb_labs(
title = "Solar production (2017-06-12)",
y = "In megawatt (MW)",
caption = "Data source: RTE (https://opendata.reseaux-energies.fr/)"
)
library(billboarder)
# data
data("cdc_prod_filiere")
billboarder() %>%
bb_linechart(
data = cdc_prod_filiere[, c("date_heure", "prod_eolien", "prod_hydraulique", "prod_solaire")],
type = "area"
) %>%
bb_data(
groups = list(list("prod_eolien", "prod_hydraulique", "prod_solaire")),
names = list("prod_eolien" = "Wind", "prod_hydraulique" = "Hydraulic", "prod_solaire" = "Solar")
) %>%
bb_legend(position = "inset", inset = list(anchor = "top-right")) %>%
bb_colors_manual(
"prod_eolien" = "#238443", "prod_hydraulique" = "#225EA8", "prod_solaire" = "#FEB24C",
opacity = 0.8
) %>%
bb_y_axis(min = 0, padding = 0) %>%
bb_labs(
title = "Renewable energy production (2017-06-12)",
y = "In megawatt (MW)",
caption = "Data source: RTE (https://opendata.reseaux-energies.fr/)"
)
Use RStudio >= 1.2.0 to display in viewer.
# Generate data
dat <- data.frame(
date = seq.Date(Sys.Date(), length.out = 20, by = "day"),
y1 = round(rnorm(20, 100, 15)),
y2 = round(rnorm(20, 100, 15))
)
dat$ymin1 <- dat$y1 - 5
dat$ymax1 <- dat$y1 + 5
dat$ymin2 <- dat$y2 - sample(3:15, 20, TRUE)
dat$ymax2 <- dat$y2 + sample(3:15, 20, TRUE)
# Make chart : use ymin & ymax aes for range
billboarder(data = dat) %>%
bb_linechart(
mapping = aes(x = date, y = y1, ymin = ymin1, ymax = ymax1),
type = "area-line-range"
) %>%
bb_linechart(
mapping = aes(x = date, y = y2, ymin = ymin2, ymax = ymax2),
type = "area-spline-range"
) %>%
bb_y_axis(min = 50)
Create histograms with a numeric vector (or data.frame
)
:
With a grouping variable :
# Generate some data
dat <- data.frame(
sample = c(rnorm(n = 1e4, mean = 1), rnorm(n = 1e4, mean = 2)),
group = rep(c("A", "B"), each = 1e4), stringsAsFactors = FALSE
)
# Mean by groups
samples_mean <- tapply(dat$sample, dat$group, mean)
# histogram !
billboarder() %>%
bb_histogram(data = dat, x = "sample", group = "group", binwidth = 0.25) %>%
bb_x_grid(
lines = list(
list(value = unname(samples_mean['A']), text = "mean of sample A"),
list(value = unname(samples_mean['B']), text = "mean of sample B")
)
)
Density plot with the same data :
With single serie:
Multiple series and with data in long format:
Gauge can be created with:
or with function bauge()
which had special output and
render function in shiny:
Multiple values gauge are also possible:
Create a treemap chart with:
data("mpg", package = "ggplot2")
billboarder() %>%
bb_treemapchart(
data = table(manufacturer = mpg$manufacturer),
mapping = aes(x = manufacturer, y = Freq),
label = list(show = TRUE, threshold = 0.03),
tile = "binary" # or "slice" or "dice"
) %>%
bb_data(
labels = list(colors = "#FFF")
) %>%
bb_color(
palette = colorRampPalette(c("#08519C", "#9ECAE1"))(15) #15 = n manufacturer
)