# Port MATLAB bounding ellipsoid code to Python

Facebook and Stack Exchange are now working together to support the Facebook developer community. Facebook engineers participate here along with the best Facebook developers in the world. If you have a technical question about Facebook, this is the best place to ask.

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. – Chris Ferrie Dec 25 '12 at 21:03 Yes, `np.multiply.outer(c,c)` would also work, and is faster for large `len(c)`. – unutbu Dec 25 '12 at 23:50