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The main function of deeptime is
coord_geo()
, which functions just like
coord_trans()
from {ggplot2}
. You can use this
function to add highly customizable timescales to a wide variety of
ggplots. Before we begin, let’s load some necessary packages first.
# Load deeptime
library(deeptime)
# Load other packages
library(ggplot2)
library(dplyr)
# Load divDyn for coral data
library(divDyn)
data(corals)
# Load gsloid for oxygen isotope data
library(gsloid)
First, let’s summarize some coral data from the divDyn
package to generate a diversity curve that we’ll be able to plot:
# this is not a proper diversity curve but it gets the point across
coral_div <- corals %>%
filter(stage != "") %>%
group_by(period, stage) %>%
summarise(n = n()) %>%
mutate(stage_age = (stages$max_age[match(stage, stages$name)] +
stages$min_age[match(stage, stages$name)]) / 2)
Now, we can plot the data and add a geological timescale. The default
behavior is to add the ICS periods to the bottom axis. The data used for
this is included in the package (?periods
) along with data
for ?eons
, ?stages
, ?epochs
, and
?eras
. Note that the function assumes that age is
decreasing towards the present.
ggplot(coral_div) +
geom_line(aes(x = stage_age, y = n)) +
scale_x_reverse("Age (Ma)") +
ylab("Coral Genera") +
coord_geo(xlim = c(250, 0), ylim = c(0, 1700)) +
theme_classic()
You can add the timescale to whichever axis you’d like by setting the
pos
argument. For example, pos = "left"
can be
used to put the timescale on the left axis. Also, note that we’re using
the “Geomagnetic Polarity Chron” timescale here. This is one of more
than 35 regional and global timescales that are available through
deeptime from the Macrostrat
database (see get_scale_data()
).
ggplot(lisiecki2005) +
geom_line(aes(x = d18O, y = Time / 1000), orientation = "y") +
scale_y_reverse("Time (Ma)") +
scale_x_reverse() +
coord_geo(
dat = "Geomagnetic Polarity Chron", xlim = c(6, 2), ylim = c(6, 0),
pos = "left", rot = 90
) +
theme_classic()
You can also add multiple timescales by providing a list for
pos
. Other arguments can be lists or single values (either
of which will be recycled if necessary). In this case we are adding the
“Geomagnetic Polarity Chron” timescale to the left axis and the
“Planktic foraminiferal Primary Biozones” timescale to the right
axis.
# uses the oxygen isotope data from above
ggplot(lisiecki2005) +
geom_line(aes(x = d18O, y = Time / 1000), orientation = "y") +
scale_y_reverse("Time (Ma)") +
scale_x_reverse() +
coord_geo(
dat = list("Geomagnetic Polarity Chron", "Planktic foraminiferal Primary Biozones"),
xlim = c(6, 2), ylim = c(5.5, 0), pos = list("l", "r"),
rot = 90, skip = "PL4", size = list(5, 4)
) +
theme_classic()
You can even stack multiple timescales on the same side. Scales are added from the inside to the outside. Here we are stacking periods and eras.
# uses the coral diversity data from above
ggplot(coral_div) +
geom_line(aes(x = stage_age, y = n)) +
scale_x_reverse("Age (Ma)") +
ylab("Coral Genera") +
coord_geo(
dat = list("periods", "eras"), xlim = c(250, 0), ylim = c(0, 1700),
pos = list("b", "b"), abbrv = list(TRUE, FALSE)
) +
theme_classic()
coord_geo()
synergizes well with faceted plots. You can
change on which facets the timescale is plotted by changing the
scales
argument in facet_wrap()
. The default
behavior is to only include the timescale on the bottom-most panel. This
behavior works similarly with facet_grid()
.
# uses the coral occurrence data from above
coral_div_diet <- corals %>%
filter(stage != "") %>%
group_by(diet, stage) %>%
summarise(n = n()) %>%
mutate(stage_age = (stages$max_age[match(stage, stages$name)] +
stages$min_age[match(stage, stages$name)]) / 2)
ggplot(coral_div_diet) +
geom_line(aes(x = stage_age, y = n)) +
scale_x_reverse("Age (Ma)") +
ylab("Coral Genera") +
coord_geo(xlim = c(250, 0)) +
theme_classic() +
facet_wrap(~diet, nrow = 3)
By specifying scales = "free_x"
, you can add a
geological time scale to each panel.
coord_geo()
can use the {ggfittext}
package
to resize the interval labels. This can be enabled by setting
size
to "auto"
. Additional arguments can be
passed to ggfittext::geom_fit_text()
as a list using the
fittext_args
argument.
coord_geo()
will automatically detect if your axis is
discrete. The categories of the discrete axis (which can be reordered
using the limits
argument of
scale_x_discrete()
/scale_y_discrete()
) should
match the name
column of the timescale data
(dat
). You can use the arguments of theme()
and scale_[x/y]_discrete()
to optionally remove the labels
and tick marks.
# use the coral occurrence data from above
coral_div_dis <- corals %>%
filter(period != "") %>%
group_by(diet, period) %>%
summarise(n = n()) %>%
mutate(period_age = (periods$max_age[match(period, periods$name)] +
periods$min_age[match(period, periods$name)]) / 2) %>%
arrange(-period_age)
ggplot(coral_div_dis) +
geom_col(aes(x = period, y = n, fill = diet)) +
scale_x_discrete("Period",
limits = unique(coral_div_dis$period), labels = NULL,
expand = expansion(add = .5)
) +
scale_y_continuous(expand = c(0, 0)) +
scale_fill_viridis_d("Diet") +
ylab("Coral Genera") +
coord_geo(expand = TRUE, skip = NULL, abbrv = TRUE) +
theme_classic() +
theme(axis.ticks.length.x = unit(0, "lines"))
You can also supply your own pre-discretized scale data by setting
the dat_is_discrete
parameter to TRUE
. Custom
scales should always have name
, max_age
, and
min_age
columns. Optional columns include abbr
for abbreviations, color
for background colors, and
lab_color
for interval label colors. You can even have one
scale with auto-discretized intervals and one scale with pre-discretized
intervals.
eras_custom <- data.frame(
name = c("Mesozoic", "Cenozoic"), max_age = c(0.5, 3.5),
min_age = c(3.5, 6.5), color = c("#67C5CA", "#F2F91D")
)
ggplot(coral_div_dis) +
geom_col(aes(x = period, y = n, fill = diet)) +
scale_x_discrete(NULL,
limits = unique(coral_div_dis$period), labels = NULL,
expand = expansion(add = .5)
) +
scale_y_continuous(expand = c(0, 0)) +
scale_fill_viridis_d("Diet") +
ylab("Coral Genera") +
coord_geo(
dat = list("periods", eras_custom), pos = c("b", "b"), expand = TRUE,
skip = NULL, abbrv = list(TRUE, FALSE), dat_is_discrete = list(FALSE, TRUE)
) +
theme_classic() +
theme(axis.ticks.length.x = unit(0, "lines"))
Looking to learn about more advanced features of deeptime? Look no further:
These binaries (installable software) and packages are in development.
They may not be fully stable and should be used with caution. We make no claims about them.
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