EDIT:
I present below a sample silhouette implementation in both MATLAB and Python/Numpy (keep in mind that I am more fluent in MATLAB):
function s = mySilhouette(X, IDX)
%# X : matrix of size N-by-p, data where rows are instances
%# IDX: vector of size N, cluster index of each instance (starting from 1)
%# s : vector of size N, silhouette score value of each instance
N = size(X,1); %# number of instances
K = numel(unique(IDX)); %# number of clusters
%# compute pairwise distance matrix
D = squareform( pdist(X,'euclidean').^2 );
%# indices belonging to each cluster
kIndices = accumarray(IDX, 1:N, [K 1], @(x){sort(x)});
%# compute a,b,s for each instance
%# a(i): average distance from i to all other data within the same cluster.
%# b(i): lowest average dist from i to the data of another single cluster
a = zeros(N,1);
b = zeros(N,1);
for i=1:N
ind = kIndices{IDX(i)}; ind = ind(ind~=i);
a(i) = mean( D(i,ind) );
b(i) = min( cellfun(@(ind) mean(D(i,ind)), kIndices([1:K]~=IDX(i))) );
end
s = (b-a) ./ max(a,b);
end
To emulate the plot from the silhouette function in MATLAB, we group the silhouette values by cluster, sort within each, then plot the bars horizontally. MATLAB adds NaNs to separate the bars from the different clusters, I found it easier to simply color-code the bars:
%# sample data
load fisheriris
X = meas;
N = size(X,1);
%# cluster and compute silhouette score
K = 3;
[IDX,C] = kmeans(X, K, 'distance','sqEuclidean');
s = mySilhouette(X, IDX);
%# plot
[~,ord] = sortrows([IDX s],[1 -2]);
indices = accumarray(IDX(ord), 1:N, [K 1], @(x){sort(x)});
ytick = cellfun(@(ind) (min(ind)+max(ind))/2, indices);
ytickLabels = num2str((1:K)','%d'); %#'
h = barh(1:N, s(ord),'hist');
set(h, 'EdgeColor','none', 'CData',IDX(ord))
set(gca, 'CLim',[1 K], 'CLimMode','manual')
set(gca, 'YDir','reverse', 'YTick',ytick, 'YTickLabel',ytickLabels)
xlabel('Silhouette Value'), ylabel('Cluster')
%# compare against SILHOUETTE
figure, silhouette(X,IDX)
And here is what I came up with in Python:
import numpy as np
from scipy.cluster.vq import kmeans2
from scipy.spatial.distance import pdist, squareform
from scikits.learn import datasets
import matplotlib.pyplot as plt
from matplotlib import cm
def silhouette(X, cIDX):
"""
Computes the silhouette score for each instance of a clustered dataset,
which is defined as:
s(i) = (b(i)-a(i)) / max{a(i),b(i)}
with:
-1 <= s(i) <= 1
Args:
X : A M-by-N array of M observations in N dimensions
cIDX : array of len M containing cluster indices (starting from zero)
Returns:
s : silhouette value of each observation
"""
N = X.shape[0] # number of instances
K = len(np.unique(cIDX)) # number of clusters
# compute pairwise distance matrix
D = squareform(pdist(X))
# indices belonging to each cluster
kIndices = [np.flatnonzero(cIDX==k) for k in range(K)]
# compute a,b,s for each instance
a = np.zeros(N)
b = np.zeros(N)
for i in range(N):
# instances in same cluster other than instance itself
a[i] = np.mean( [D[i][ind] for ind in kIndices[cIDX[i]] if ind!=i] )
# instances in other clusters, one cluster at a time
b[i] = np.min( [np.mean(D[i][ind])
for k,ind in enumerate(kIndices) if cIDX[i]!=k] )
s = (b-a)/np.maximum(a,b)
return s
def main():
# load Iris dataset
data = datasets.load_iris()
X = data['data']
# cluster and compute silhouette score
K = 3
C, cIDX = kmeans2(X, K)
s = silhouette(X, cIDX)
# plot
order = np.lexsort((-s,cIDX))
indices = [np.flatnonzero(cIDX[order]==k) for k in range(K)]
ytick = [(np.max(ind)+np.min(ind))/2 for ind in indices]
ytickLabels = ["%d" % x for x in range(K)]
cmap = cm.jet( np.linspace(0,1,K) ).tolist()
clr = [cmap[i] for i in cIDX[order]]
fig = plt.figure()
ax = fig.add_subplot(111)
ax.barh(range(X.shape[0]), s[order], height=1.0,
edgecolor='none', color=clr)
ax.set_ylim(ax.get_ylim()[::-1])
plt.yticks(ytick, ytickLabels)
plt.xlabel('Silhouette Value')
plt.ylabel('Cluster')
plt.show()
if __name__ == '__main__':
main()
