# Port MATLAB bounding ellipsoid code to Python

MATLAB code exists to find the so-called "minimum volume enclosing ellipsoid" (e.g. here, also here). I'll paste the relevant part for convenience:

``````function [A , c] = MinVolEllipse(P, tolerance)
[d N] = size(P);

Q = zeros(d+1,N);
Q(1:d,:) = P(1:d,1:N);
Q(d+1,:) = ones(1,N);

count = 1;
err = 1;
u = (1/N) * ones(N,1);

while err > tolerance,
X = Q * diag(u) * Q';
M = diag(Q' * inv(X) * Q);
[maximum j] = max(M);
step_size = (maximum - d -1)/((d+1)*(maximum-1));
new_u = (1 - step_size)*u ;
new_u(j) = new_u(j) + step_size;
count = count + 1;
err = norm(new_u - u);
u = new_u;
end

U = diag(u);
A = (1/d) * inv(P * U * P' - (P * u)*(P*u)' );
c = P * u;
``````

Here is some MATLAB test code:

``````points  = [[ 0.53135758, -0.25818091, -0.32382715],
[ 0.58368177, -0.3286576,  -0.23854156,],
[ 0.18741533,  0.03066228, -0.94294771],
[ 0.65685862, -0.09220681, -0.60347573],
[ 0.63137604, -0.22978685, -0.27479238],
[ 0.59683195, -0.15111101, -0.40536606],
[ 0.68646128,  0.0046802,  -0.68407367],
[ 0.62311759,  0.0101013,  -0.75863324]];

[A centroid] = minVolEllipse(points',0.001);
A
[~, D, V] = svd(A);

rx = 1/sqrt(D(1,1));
ry = 1/sqrt(D(2,2));
rz = 1/sqrt(D(3,3));

[u v] = meshgrid(linspace(0,2*pi,20),linspace(-pi/2,pi/2,10));

x = rx*cos(u').*cos(v');
y = ry*sin(u').*cos(v');
z = rz*sin(v');

for idx = 1:20,
for idy = 1:10,
point = [x(idx,idy) y(idx,idy) z(idx,idy)]';
P = V * point;
x(idx,idy) = P(1)+centroid(1);
y(idx,idy) = P(2)+centroid(2);
z(idx,idy) = P(3)+centroid(3);
end
end

figure
plot3(points(:,1),points(:,2),points(:,3),'.');
hold on;
mesh(x,y,z);
axis square;
alpha 0;
``````

which will produce the the covariance matrix:

``````A =
47.3693 -116.0758  -79.1861
-116.0758  458.0874  280.0656
-79.1861  280.0656  179.3886
``````

Now, here is my attempt at port this code to Python (2.7):

``````from __future__ import division
import numpy as np
import numpy.linalg as la

def mvee(points,tol=0.001):
N, d = points.shape

Q = np.zeros([N,d+1])
Q[:,0:d] = points[0:N,0:d]
Q[:,d] = np.ones([1,N])

Q = np.transpose(Q)
points = np.transpose(points)
count = 1
err = 1
u = (1/N) * np.ones(shape = (N,))

while err > tol:

X = np.dot(np.dot(Q, np.diag(u)), np.transpose(Q))
M = np.diag( np.dot(np.dot(np.transpose(Q), la.inv(X)),Q))
jdx = np.argmax(M)
step_size = (M[jdx] - d - 1)/((d+1)*(M[jdx] - 1))
new_u = (1 - step_size)*u
new_u[jdx] = new_u[jdx] + step_size
count = count + 1
err = la.norm(new_u - u)
u = new_u

U = np.diag(u)
c = np.dot(points,u)
A = (1/d) * la.inv(np.dot(np.dot(points,U), np.transpose(points)) - np.dot(c,np.transpose(c)) )
return A, np.transpose(c)
``````

The corresponding test code:

``````from mpl_toolkits.mplot3d import Axes3D
from mpl_toolkits.mplot3d.art3d import Poly3DCollection
import matplotlib.pyplot as plt
from scipy.spatial import Delaunay

#some random points
points = np.array([[ 0.53135758, -0.25818091, -0.32382715],
[ 0.58368177, -0.3286576,  -0.23854156,],
[ 0.18741533,  0.03066228, -0.94294771],
[ 0.65685862, -0.09220681, -0.60347573],
[ 0.63137604, -0.22978685, -0.27479238],
[ 0.59683195, -0.15111101, -0.40536606],
[ 0.68646128,  0.0046802,  -0.68407367],
[ 0.62311759,  0.0101013,  -0.75863324]])

# compute mvee
A, centroid = mvee(points)
print A

# point it and some other stuff
U, D, V = la.svd(A)

rx, ry, rz = [1/np.sqrt(d) for d in D]
u, v = np.mgrid[0:2*np.pi:20j,-np.pi/2:np.pi/2:10j]

x=rx*np.cos(u)*np.cos(v)
y=ry*np.sin(u)*np.cos(v)
z=rz*np.sin(v)

for idx in xrange(x.shape[0]):
for idy in xrange(y.shape[1]):
x[idx,idy],y[idx,idy],z[idx,idy] = np.dot(np.transpose(V),np.array([x[idx,idy],y[idx,idy],z[idx,idy]])) + centroid

fig = plt.figure()
ax.scatter(points[:,0],points[:,1],points[:,2])
ax.plot_surface(x, y, z, cstride = 1, rstride = 1, alpha = 0.1)
plt.show()
``````

produces this:

``````[[ 0.84650504 -1.40006147  0.39857055]
[-1.40006147  2.60678264 -1.52583781]
[ 0.39857055 -1.52583781  1.04581752]]
``````

Clearly different. What gives?

Using Octave, I found that after the while-loop in MinVolEllipse ends,

``````u =

0.0053531
0.2384227
0.2476188
0.0367063
0.0257947
0.2124423
0.0838103
0.1498518
``````

This agrees with the result for `u` found by the Python function `mvee`. More debugging print statements on the Octave side yield

``````(P*u) =

0.50651
-0.11166
-0.57847
``````

and

``````(P*u)*(P*u)' =

0.256555  -0.056556  -0.293002
-0.056556   0.012467   0.064590
-0.293002   0.064590   0.334628
``````

But on the Python side,

``````c = np.dot(points.T,u)
print(c)
``````

yields

``````[ 0.50651212 -0.11165724 -0.57847018]
``````

and

``````print(np.dot(c,np.transpose(c)))
``````

yields

``````0.60364961984    # <-- This should equal (P*u)*(P*u)', a 3x3 matrix.
``````

Once you know the problem, the solution is simple. `(P*u)*(P*u)'` can be computed with:

``````np.multiply.outer(c,c)
``````

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

pi = np.pi
sin = np.sin
cos = np.cos

def mvee(points, tol = 0.001):
"""
Finds the ellipse equation in "center form"
(x-c).T * A * (x-c) = 1
"""
N, d = points.shape
Q = np.column_stack((points, np.ones(N))).T
err = tol+1.0
u = np.ones(N)/N
while err > tol:
# assert u.sum() == 1 # invariant
X = np.dot(np.dot(Q, np.diag(u)), Q.T)
M = np.diag(np.dot(np.dot(Q.T, la.inv(X)), Q))
jdx = np.argmax(M)
step_size = (M[jdx]-d-1.0)/((d+1)*(M[jdx]-1.0))
new_u = (1-step_size)*u
new_u[jdx] += step_size
err = la.norm(new_u-u)
u = new_u
c = np.dot(u,points)
A = la.inv(np.dot(np.dot(points.T, np.diag(u)), points)
- np.multiply.outer(c,c))/d
return A, c

#some random points
points = np.array([[ 0.53135758, -0.25818091, -0.32382715],
[ 0.58368177, -0.3286576,  -0.23854156,],
[ 0.18741533,  0.03066228, -0.94294771],
[ 0.65685862, -0.09220681, -0.60347573],
[ 0.63137604, -0.22978685, -0.27479238],
[ 0.59683195, -0.15111101, -0.40536606],
[ 0.68646128,  0.0046802,  -0.68407367],
[ 0.62311759,  0.0101013,  -0.75863324]])

# Singular matrix error!
# points = np.eye(3)

A, centroid = mvee(points)
U, D, V = la.svd(A)
rx, ry, rz = 1./np.sqrt(D)
u, v = np.mgrid[0:2*pi:20j, -pi/2:pi/2:10j]

def ellipse(u,v):
x = rx*cos(u)*cos(v)
y = ry*sin(u)*cos(v)
z = rz*sin(v)
return x,y,z

E = np.dstack(ellipse(u,v))
E = np.dot(E,V) + centroid
x, y, z = np.rollaxis(E, axis = -1)

fig = plt.figure()

ax.plot_surface(x, y, z, cstride = 1, rstride = 1, alpha = 0.05)
ax.scatter(points[:,0],points[:,1],points[:,2])

plt.show()
``````

By the way, this computation uses a lot of matrix multiplication, which when using `np.dot` looks rather verbose. If we convert the NumPy arrays into NumPy matrices, then matrix multiplication can be expressed with `*`. For example,

``````A = la.inv(np.dot(np.dot(points.T, np.diag(u)), points)
- np.dot(c[:, np.newaxis], c[np.newaxis, :]))/d
``````

becomes

``````A = la.inv(points.T*np.diag(u)*points - c.T*c)/d
``````

Since readability counts, you may wish to do the main computation with NumPy matrices:

``````def mvee(points, tol = 0.001):
"""
Find the minimum volume ellipse.
Return A, c where the equation for the ellipse given in "center form" is
(x-c).T * A * (x-c) = 1
"""
points = np.asmatrix(points)
N, d = points.shape
Q = np.column_stack((points, np.ones(N))).T
err = tol+1.0
u = np.ones(N)/N
while err > tol:
# assert u.sum() == 1 # invariant
X = Q * np.diag(u) * Q.T
M = np.diag(Q.T * la.inv(X) * Q)
jdx = np.argmax(M)
step_size = (M[jdx]-d-1.0)/((d+1)*(M[jdx]-1.0))
new_u = (1-step_size)*u
new_u[jdx] += step_size
err = la.norm(new_u-u)
u = new_u
c = u*points
A = la.inv(points.T*np.diag(u)*points - c.T*c)/d
return np.asarray(A), np.squeeze(np.asarray(c))
``````
• Awesome! Thanks. I was also pointed to numpy.outer by my Google+ followers. Dec 25, 2012 at 21:03
• Yes, `np.multiply.outer(c,c)` would also work, and is faster for large `len(c)`. Dec 25, 2012 at 23:50
• Is there a way to just get the (x,y),(x,z),(y,z) projections? Nov 21, 2013 at 18:43