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I have some dots in a 3 dimensional space and would like to cluster them. I know Pythons module "cluster", but it has only K-Means. Do you know a module which has FCM (Fuzzy C-Means)?

(If you know some other python modules which are related to clustering you could name them as a bonus. But the important question is the one for a FCM-algorithm in python.)

Matlab

It seems to be quite easy to use FCM in Matlab (example). Isn't something like this available for Python?

NumPy, SciPy and Sage

I didn't find FCM in NumPy, SciPy or Sage. I've downloaded the documentation and searched for it. No results

Python-cluster

It seems like the cluster module will add fuzzy C-Means with the next version (see Roadmap). But I need it now

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4 Answers 4

7

PEACH will provide some Fuzzy C-Means functionality: http://code.google.com/p/peach/

However there doesn't seem to be any usable documentation as the wiki is empty. An example for using FCM with PEACH can be found on its website.

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  • I've just installed it and called the help: class FuzzyCMeans - Use this class to instantiate a fuzzy c-means object. The object must be given a training set and initial conditions. I don't have a training-set. Jul 19, 2011 at 17:42
  • 1
    You can also see the code and help at peach.googlecode.com/svn/trunk/peach/fuzzy/cmeans.py, it says that the training set is just the data you want to be clustered. the provided example shows, that you can chose the initial conditions randomly Jul 19, 2011 at 19:43
7

Have a look at scikit-fuzzy package. It has the very basic fuzzy logic functionality, including fuzzy c-means clustering.

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Python

There is a fuzzy-c-means package in the PyPI. Check out the link : fuzzy-c-means Python

This is the simplest way to use FCM in python. Hope it helps.

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I have done it from scratch, using K++ initialization (with fixed seeds and 5 centroids. It should't be too difficult to addapt it to your desired number of centroids):

# K++ initialization Algorithm:
import random
def initialize(X, K):
    C = [X[0]]
    for k in range(1, K):
        D2 = scipy.array([min([scipy.inner(c-x,c-x) for c in C]) for x in X])
        probs = D2/D2.sum()
        cumprobs = probs.cumsum()
        np.random.seed(20)            # fixxing seeds
        #random.seed(0)               # fixxing seeds
        r = scipy.rand()        
        for j,p in enumerate(cumprobs):
            if r < p:
                i = j
                break
        C.append(X[i])
    return C

a = initialize(data2,5)   # "a" is the centroids initial array... I used 5 centroids

# Now the Fuzzy c means algorithm:
m = 1.5     # Fuzzy parameter (it can be tuned)
r = (2/(m-1))

# Initial centroids:
c1,c2,c3,c4,c5 = a[0],a[1],a[2],a[3],a[4]

# prepare empty lists to add the final centroids:
cc1,cc2,cc3,cc4,cc5 = [],[],[],[],[]

n_iterations = 10000

for j in range(n_iterations):
    u1,u2,u3,u4,u5 = [],[],[],[],[]

    for i in range(len(data2)):
        # Distances (of every point to each centroid):
        a = LA.norm(data2[i]-c1)    
        b = LA.norm(data2[i]-c2)
        c = LA.norm(data2[i]-c3)
        d = LA.norm(data2[i]-c4)
        e = LA.norm(data2[i]-c5)

        # Pertenence matrix vectors:
        U1 = 1/(1 + (a/b)**r + (a/c)**r + (a/d)**r + (a/e)**r) 
        U2 = 1/((b/a)**r + 1 + (b/c)**r + (b/d)**r + (b/e)**r)
        U3 = 1/((c/a)**r + (c/b)**r + 1 + (c/d)**r + (c/e)**r)
        U4 = 1/((d/a)**r + (d/b)**r + (d/c)**r + 1 + (d/e)**r)
        U5 = 1/((e/a)**r + (e/b)**r + (e/c)**r + (e/d)**r + 1)

        # We will get an array of n row points x K centroids, with their degree of pertenence       
        u1.append(U1)
        u2.append(U2)
        u3.append(U3)
        u4.append(U4)
        u5.append(U5)        

    # now we calculate new centers:
    c1 = (np.array(u1)**2).dot(data2) / np.sum(np.array(u1)**2)
    c2 = (np.array(u2)**2).dot(data2) / np.sum(np.array(u2)**2)
    c3 = (np.array(u3)**2).dot(data2) / np.sum(np.array(u3)**2)
    c4 = (np.array(u4)**2).dot(data2) / np.sum(np.array(u4)**2)
    c5 = (np.array(u5)**2).dot(data2) / np.sum(np.array(u5)**2)

    cc1.append(c1)
    cc2.append(c2)
    cc3.append(c3)
    cc4.append(c4)
    cc5.append(c5) 

    if (j>5):  
        change_rate1 = np.sum(3*cc1[j] - cc1[j-1] - cc1[j-2] - cc1[j-3])/3
        change_rate2 = np.sum(3*cc2[j] - cc2[j-1] - cc2[j-2] - cc2[j-3])/3
        change_rate3 = np.sum(3*cc3[j] - cc3[j-1] - cc3[j-2] - cc3[j-3])/3
        change_rate4 = np.sum(3*cc4[j] - cc4[j-1] - cc4[j-2] - cc4[j-3])/3
        change_rate5 = np.sum(3*cc5[j] - cc5[j-1] - cc5[j-2] - cc5[j-3])/3        
        change_rate = np.array([change_rate1,change_rate2,change_rate3,change_rate4,change_rate5])
        changed = np.sum(change_rate>0.0000001)
        if changed == 0:
            break

print(c1)  # to check a centroid coordinates   c1 - c5 ... they are the last centroids calculated, so supposedly they converged.
print(U)  # this is the degree of pertenence to each centroid (so n row points x K centroids columns).

I know it is not very pythonic, but I hope it can be a starting point for your complete fuzzy C means algorithm. I think that "soft clustering" is the way to go when data is not easily separable (for example, when "t-SNE visualization" show all data together instead of showing groups clearly separated. In this case, forcing data to pertain strictly to only one clustering can be dangerous). I would give a try with m = 1.1, to m = 2.0, so you can see how the fuzzy parameter affects to the pertenence matrix.

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