Interesting question. Thank you for bringing this paper to my attention. PDF link here of the original paper.

In simple terms, cluster centers are initially chosen at random from the set of input observation vectors, where the probability of choosing vector `x`

is high if `x`

is not near any previously chosen centers.

Here is a one-dimensional example. Our observations are [0, 1, 2, 3, 4]. Let the first center, `c1`

, be 0. The probability that the next cluster center, `c2`

, is x is proportional to `||c1-x||^2`

. So, P(c2 = 1) = 1a, P(c2 = 2) = 4a, P(c2 = 3) = 9a, P(c2 = 4) = 16a, where a = 1/(1+4+9+16).

Suppose c2=4. Then, P(c3 = 1) = 1a, P(c3 = 2) = 4a, P(c3 = 3) = 1a, where a = 1/(1+4+1).

I've coded the initialization procedure in Python; I don't know if this helps you.

```
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()
r = scipy.rand()
for j,p in enumerate(cumprobs):
if r < p:
i = j
break
C.append(X[i])
return C
```

EDIT with clarification: The output of `cumsum`

gives us boundaries to partition the interval [0,1]. These partitions have length equal to the probability of the corresponding point being chosen as a center. So then, since `r`

is uniformly chosen between [0,1], it will fall into exactly one of these intervals (because of `break`

). The `for`

loop checks to see which partition `r`

is in.

Example:

```
probs = [0.1, 0.2, 0.3, 0.4]
cumprobs = [0.1, 0.3, 0.6, 1.0]
if r < cumprobs[0]:
# this event has probability 0.1
i = 0
elif r < cumprobs[1]:
# this event has probability 0.2
i = 1
elif r < cumprobs[2]:
# this event has probability 0.3
i = 2
elif r < cumprobs[3]:
# this event has probability 0.4
i = 3
```