# How can an almost arbitrary plane in a 3D dataset be plotted by matplotlib?

There is an array containing 3D data of shape e.g. (64,64,64), how do you plot a plane given by a point and a normal (similar to hkl planes in crystallography), through this dataset? Similar to what can be done in MayaVi by rotating a plane through the data.

The resulting plot will contain non-square planes in most cases. Can those be done with matplotlib (some sort of non-rectangular patch)?

Edit: I almost solved this myself (see below) but still wonder how non-rectangular patches can be plotted in matplotlib...?

Edit: Due to discussions below I restated the question.

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You should go with a general solution that does interpolation through an arbitrary plane, as Thorsten suggested. When an interpolated value falls outside your cube of data, it will be assigned a `nan`, because it would have to be extrapolated, not interpolated. This will make the area outside the actual cross section of your cube to look different when you plot it, without having to worry about determining the exact boundaries. –  Jaime Jan 3 '13 at 18:52
Interesting point about the `nan`. This would't tell matplotlib about the borders of the patch though. This is important to me because if you want to publish something like that it's nicer to have a plot with correct boundaries. –  BandGap Jan 3 '13 at 20:13

This is funny, a similar question I replied to just today. The way to go is: interpolation. You can use griddata from scipy.interpolate:

Griddata

This page features a very nice example, and the signature of the function is really close to your data.

You still have to somehow define the points on you plane for which you want to interpolate the data. I will have a look at this, my linear algebra lessons where a couple of years ago

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I don't think this is how MayaVi does it. As far as I understand the functioin you linked to, you would extract those points from my dataset which lie roughly on a specified plane and interpolate between them? –  BandGap Jan 3 '13 at 13:28
No, I would interpolate in three dimensions. You give the information you have about your scalar field and the 3d-points where you want to interpolate. –  Thorsten Kranz Jan 3 '13 at 13:39
I don't think interpolation is necessary here at all. You could use interpolationt if you needed more datapoints than already supplied by the dataset. In the other question you answered you are correct but here the interpolation will be done by imshow, if you don't use 'Nearest' ... –  BandGap Jan 3 '13 at 15:47
You definitely will need to interpolate. You have limited data (e.g. 64**3) but unlimited possible orientations of your plane. As long as you keep the "normal" parallel to one of the dimensions and move the "point" only in 64 steps, you're fine without interpolation. But as soon as these become arbitrary, you most likely won't hit any of your data points with your plane. So how can you determine the values on the plane? Interpolation. –  Thorsten Kranz Jan 3 '13 at 16:03
Ok I understand what you mean. I didn't think of arbitrary planes when I stated the question but more of hkl planes like they are used in crystallography... Not that arbitrary in the end :) Sorry for not making that clear enough. –  BandGap Jan 3 '13 at 16:17

For the reduced requirements, I prepared a simple example

``````import numpy as np
import pylab as plt

data = np.arange((64**3))
data.resize((64,64,64))

def get_slice(volume, orientation, index):
orientation2slicefunc = {
"x" : lambda ar:ar[index,:,:],
"y" : lambda ar:ar[:,index,:],
"z" : lambda ar:ar[:,:,index]
}
return orientation2slicefunc[orientation](volume)

plt.subplot(221)
plt.imshow(get_slice(data, "x", 10), vmin=0, vmax=64**3)

plt.subplot(222)
plt.imshow(get_slice(data, "x", 39), vmin=0, vmax=64**3)

plt.subplot(223)
plt.imshow(get_slice(data, "y", 15), vmin=0, vmax=64**3)
plt.subplot(224)
plt.imshow(get_slice(data, "z", 25), vmin=0, vmax=64**3)

plt.show()
``````

This leads to the following plot:

The main trick is dictionary mapping orienations to lambda-methods, which saves us from writing annoying if-then-else-blocks. Of course you can decide to give different names, e.g., numbers, for the orientations.

Maybe this helps you.

Thorsten

P.S.: I didn't care about "IndexOutOfRange", for me it's o.k. to let this exception pop out since it is perfectly understandable in this context.

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+1 For the nice sleek code, but that is less than the OP wants, see en.wikipedia.org/wiki/Miller_index and en.wikipedia.org/wiki/Reciprocal_lattice#Simple_cubic_lattice, so I think he is after planes with normal vectors of the form `[i/64, j/64, k/64]` where `i`, `j` and `k` are all integers, and going through a point `[x, y, z]` where all values are integers in `[0, 64)`. –  Jaime Jan 3 '13 at 18:58
-1 This is not even remotely what was asked. And why would I write a function as you did in the first place? plt.imshow(data[index,:,:] ... ) would do the exact same thing without introducing illegible code. –  BandGap Jan 3 '13 at 20:07
The reason for my function is: orientation is meant as a minimal "normal-vector" - which is only o.k. when the normals have to be parallel to one of the edges of the lattice. Now I understood that this is not what you want. I used lambdas as your suggestion (data[index,:,:]) only works if you now which axis is to be indexed - but we do not know in my example, it depends on the "orientation" –  Thorsten Kranz Jan 3 '13 at 21:19
But why wouldn't we know which axis we want? Why would we rather know it's x,y or z? –  BandGap Jan 3 '13 at 22:11
When we execute the funtion, we know: n=[0,0,1] -> "z"; n=[1,0,0] -> "x" But when we define the function, we don't. –  Thorsten Kranz Jan 3 '13 at 23:16

I have the penultimate solution for this problem. Partially solved by using the second answer to How to plot a plane in Matlab or scipy/matplotlib :

``````# coding: utf-8
import numpy as np
from matplotlib.pyplot import imshow,show

A=np.empty((64,64,64)) #This is the data array
def f(x,y):
return np.sin(x/(2*np.pi))+np.cos(y/(2*np.pi))
xx,yy= np.meshgrid(range(64), range(64))
for x in range(64):
A[:,:,x]=f(xx,yy)*np.cos(x/np.pi)

N=np.zeros((64,64))
"""This is the plane we cut from A.
It should be larger than 64, due to diagonal planes being larger.
Will be fixed."""

normal=np.array([-1,-1,1]) #Define cut plane here. Normal vector components restricted to integers
point=np.array([0,0,0])
d = -np.sum(point*normal)

def plane(x,y): # Get plane's z values
return (-normal[0]*x-normal[1]*y-d)/normal[2]

def getZZ(x,y): #Get z for all values x,y. If z>64 it's out of range
for i in x:
for j in y:
if plane(i,j)<64:
N[i,j]=A[i,j,plane(i,j)]

getZZ(range(64),range(64))
imshow(N, interpolation="Nearest")
show()
``````

It's not the ultimate solution since the plot is not restricted to points having a z value, planes larger than 64 * 64 are not accounted for and the planes have to be defined at (0,0,0).

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There are lots of suboptimal things in your code, maybe even some plain errors. The way to go is what Thorsten pointed out, if he doesn't get around to completing it during the day I will give it a shot. –  Jaime Jan 3 '13 at 15:46
@Jaime: Could you be more specific on what is a 'plain error' in my code? Also see my last comment to Thorsten's answer concerning the interpolation. –  BandGap Jan 3 '13 at 15:49
Seems like you are really just interested in the limited solution. If so, things become easier, sure. –  Thorsten Kranz Jan 3 '13 at 16:15
Indeed. See comment above. –  BandGap Jan 3 '13 at 16:19
The "plain error" is in the line "from matplotlib.pyploy import imshow,show" –  Thorsten Kranz Jan 3 '13 at 16:31