# How to do a 3D revolution plot in matplotlib?

Suppose you have a 2D curve, given by e.g.:

``````from matplotlib import pylab
t = numpy.linspace(-1, 1, 21)
z = -t**2
pylab.plot(t, z)
``````

which produces

I would like to perform a revolution to achieve a 3d plot (see http://reference.wolfram.com/mathematica/ref/RevolutionPlot3D.html). Plotting a 3d surface is not the problem, but it does not produce the result I'm expecting:

How can I perform a rotation of this blue curve in the 3d plot ?

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Are you asking why the blue curve is in front of the 3D surface? Matplotlib doesn't have "true" 3D plotting, so it doesn't handle occlusion of objects behind other objects, etc. If you want full 3D plotting, you'll need to use `mayavi` or something similar. (Mayavi's `mlab` interface is very easy to get started with: docs.enthought.com/mayavi/mayavi/mlab.html ) – Joe Kington Nov 17 '12 at 16:57
No, that is not the question. I added the blue curve together with the 3D surface to better specify what I want. The 3D surface is what I can get, but I want to perform a revolution with the blue curve to obtain a surface that I don't know how to get. The kind of the surfaces I wanna get are shown in the RevolutionPlot3D.html link. – mmgp Nov 17 '12 at 17:52
I suspect your problem is at least partially axis limits. In `matplotlib` you are getting a plot of all the z-values in a given x-y foot print, the mathematica examples pick a z-cut off and then makes the x-y footprint big enough to capture all of the points with z<z_cutoff (and doesn't plot data for points in the box that have z>z_cut). – tcaswell Nov 17 '12 at 18:51
Your comment makes sense, tcaswell. Is there some easy way to simulate this with matplotlib ? – mmgp Nov 17 '12 at 19:26

Your plot on your figure seems to use cartesian grid. There is some examples on the matplotlib website of 3D cylindrical functions like Z = f(R) (here: http://matplotlib.org/examples/mplot3d/surface3d_radial_demo.html). Is that what you looking for ? Below is what I get with your function Z = -R**2 :

And to add cut off to your function, use the following example: (matplotlib 1.2.0 required)

``````from mpl_toolkits.mplot3d import Axes3D
from matplotlib import cm
import matplotlib.pyplot as plt
import numpy as np

fig = plt.figure()
ax = fig.gca(projection='3d')
X = np.arange(-5, 5, 0.25)
Y = np.arange(-5, 5, 0.25)
X, Y = np.meshgrid(X, Y)

Z = -(abs(X) + abs(Y))

## 1) Initial surface
# Flatten mesh arrays, necessary for plot_trisurf function
X = X.flatten()
Y = Y.flatten()
Z = Z.flatten()

# Plot initial 3D surface with triangles (more flexible than quad)
#surfi = ax.plot_trisurf(X, Y, Z, cmap=cm.jet, linewidth=0.2)

## 2) Cut off
# Get desired values indexes
cut_idx = np.where(Z > -5)

# Apply the "cut off"
Xc = X[cut_idx]
Yc = Y[cut_idx]
Zc = Z[cut_idx]

# Plot the new surface (it would be impossible with quad grid)
surfc = ax.plot_trisurf(Xc, Yc, Zc, cmap=cm.jet, linewidth=0.2)

# You can force limit if you want to compare both graphs...
ax.set_xlim(-5,5)
ax.set_ylim(-5,5)
ax.set_zlim(-10,0)

plt.show()
``````

Result for surfi:

and surfc:

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That looks promising. How would I plot z = max(abs(xi), abs(yi)), i.e. the L1 norm ? – mmgp Nov 21 '12 at 18:39
Hum.. If you want to plot L1 norm with x and y, it's no more a revolution plot... Anyway, you can use the function numpy.where() for example, like this: Z = np.where(abs(X)>abs(Y), X, Y ) You can use another matplotlib example like this one. More generally, all matplotlib 3D examples are here. – Remy F Nov 21 '12 at 18:57
I have seen these examples before. I'm not sure why you consider a L1 norm cannot be represented in 3D by a revolution. Let us restrict it to some domain as [-1, 1], that certainly gives a 2D curve. Why can't I perform a revolution ? – mmgp Nov 21 '12 at 19:55
How do you get your 2D curve, what's its equation ? I think you need to fix either x or y in your formula z = max(abs(x), abs(y)) to have only one dimension and draw a curve. – Remy F Nov 21 '12 at 21:00
Restrict the domain of x to [-n, n], for example. In 1D we get the boring f(x) = y = abs(x). To get a concave down curve as in the earlier example we could consider f(x) = -abs(x). In 2D we can restrict both x and y to [-n, n], for example. So f(x, y) = z = -(abs(x) + abs(y)). If we instead perform z = -max(abs(x), abs(y)) then we are working with the L-infinity norm. – mmgp Nov 21 '12 at 21:28