surface3d(x, y, z, ..., normal_x=NULL, normal_y=NULL, normal_z=NULL)
terrain3d(x, y, z, ..., normal_x=NULL, normal_y=NULL, normal_z=NULL)z, or matrix of x coordinatesz, or matrix of y coordinatesrgl.material for details.z giving the coordinates of normals at
each grid pointz, with rows corresponding
to the values in x and columns corresponding to the values in
y. This is the same parametrization as used in persp.
If the x or y argument is a matrix, then it must be of the same
dimension as z, and the values in the matrix will be used for the corresponding
coordinates. This is used to plot shapes such as cylinders
where z is not a function of x and y.
If the normals are not supplied, they will be calculated automatically based
on neighbouring points.
surface3d always draws the surface with the `front' upwards
(i.e. towards higher z values). This can be used to render
the top and bottom differently; see rgl.material and
the example below.
For more flexibility in defining the surface, use rgl.surface.
surface3d and terrain3d are synonyms.rgl.material, rgl.surface.
See persp3d for a higher level interface.#
# volcano example taken from "persp"
#
data(volcano)
z <- 2 * volcano # Exaggerate the relief
x <- 10 * (1:nrow(z)) # 10 meter spacing (S to N)
y <- 10 * (1:ncol(z)) # 10 meter spacing (E to W)
zlim <- range(y)
zlen <- zlim[2] - zlim[1] + 1
colorlut <- terrain.colors(zlen) # height color lookup table
col <- colorlut[ z-zlim[1]+1 ] # assign colors to heights for each point
open3d()
surface3d(x, y, z, color=col, back="lines")Run the code above in your browser using DataLab