It is possible to transform the coordinates of your spline
data from cartesian to polar and vice versa, with
transform_coord()
. Let’s attach the package
rticulate
and load the data set tongue
.
library(rticulate)
data(tongue)
tongue
#> # A tibble: 3,612 × 28
#> speaker seconds rec_date prompt label TT_displacement TT_velocity
#> <fct> <dbl> <fct> <fct> <fct> <dbl> <dbl>
#> 1 it01 1.31 29/11/2016 15:10:57 Dico p… max_… 67.1 36.6
#> 2 it01 1.20 29/11/2016 15:11:03 Dico p… max_… 77.9 -7.73
#> 3 it01 1.08 29/11/2016 15:11:25 Dico p… max_… 65.9 21.1
#> 4 it01 1.12 29/11/2016 15:11:35 Dico p… max_… 64.4 8.76
#> 5 it01 1.42 29/11/2016 15:11:57 Dico p… max_… 76.9 -4.72
#> 6 it01 1.35 29/11/2016 15:12:53 Dico p… max_… 78.1 -5.68
#> 7 it01 1.07 29/11/2016 15:13:44 Dico p… max_… 69.9 -40.0
#> 8 it01 1.17 29/11/2016 15:13:49 Dico p… max_… 78.0 -7.31
#> 9 it01 1.28 29/11/2016 15:14:11 Dico p… max_… 67.1 34.5
#> 10 it01 1.10 29/11/2016 15:14:22 Dico p… max_… 75.9 -23.5
#> # ℹ 3,602 more rows
#> # ℹ 21 more variables: TT_abs_velocity <dbl>, TD_displacement <dbl>,
#> # TD_velocity <dbl>, TD_abs_velocity <dbl>, TR_displacement <dbl>,
#> # TR_velocity <dbl>, TR_abs_velocity <dbl>, fan_line <int>, X <dbl>, Y <dbl>,
#> # word <fct>, item <dbl>, ipa <fct>, c1 <fct>, c1_phonation <fct>,
#> # vowel <fct>, anteropost <fct>, height <fct>, c2 <fct>, c2_phonation <fct>,
#> # c2_place <fct>
Now let’s convert the cartesian coordinates to polar.
transform_coord()
converts to polar coordinates by default.
Your data set must contain columns named X
and
Y
with, respectively, the x and y
coordinates (if the columns are named differently, you will have to
rename them). The function extracts xy
data from two fan
lines (the defaults are 10
, and 25
), and it
uses these data to find the origin. By default, a column named
fan_line
is used for the fan lines number, but it can be
supplied by the user with the argument fan_line_col
as a
string.
If you have imported data using read_aaa()
, the defaults
will work, so you can just use
transform_coord(your-data)
.
polar <- tongue %>%
filter(speaker == "it01") %>%
transform_coord()
#> The origin is x = 14.3901267816422, y = -65.2315420525846.
The function returns a data set with two new columns:
radius
and theta
. It also prints the
calculated origin.
If you get an error relating to lm.fit
, try to change
the fan_lines
to values different from the default.
We can now plot the contours using polar coordinates in a cartesian system. Notice that the tip of the tongue is on the left (rather than the right, as in the original data).
polar %>%
ggplot(aes(angle, radius, colour = c2_place)) +
geom_point() +
scale_colour_discrete(name = "Place of C2") +
theme(legend.position = "top")
#> Warning: Removed 264 rows containing missing values or values outside the scale range
#> (`geom_point()`).
Plotting in polar coordinates gives a sense of the actual shape of the tongue, but it is a bit trickier and it does not look very nice… (the tip is again on the left).
polar %>%
ggplot(aes(angle, radius, colour = c2_place)) +
geom_point(alpha = 0.5) +
scale_colour_discrete(name = "Place of C2") +
coord_polar(start = pi) +
xlim(min(polar$angle) - pi / 2, max(polar$angle) + pi / 2) +
ylim(0, max(polar$radius)) +
theme_void() +
theme(legend.position = "top")
#> Warning: Removed 264 rows containing missing values or values outside the scale range
#> (`geom_point()`).