### A minor edit to answer your question about 2d:

You can use the original answer below, just take:

```
data = np.column_stack([x,y])
```

If you want to plot the centroids, it is the same as below in the original answer. If you want to color each value by the group selected, you can use `kmeans2`

```
from scipy.cluster.vq import kmeans2
centroids, ks = kmeans2(data, 3, 10)
```

To plot, pick `k`

colors, then use the `ks`

array returned by `kmeans2`

to select that color from the three colors:

```
colors = ['r', 'g', 'b']
plt.scatter(*data.T, c=np.choose(ks, colors))
plt.scatter(*centroids.T, c=colors, marker='v')
```

### original answer:

As @David points out, your `data`

is one dimensional, so the centroid for each cluster will also just be one dimensional. The reason your plot *looks* 2d is because when you run

```
plt.plot(data)
```

if `data`

is 1d, then what the function actually does is plot:

```
plt.plot(range(len(data)), data)
```

To make this clear, see this example:

```
data = np.array([3,2,3,4,3])
centroids, variances= kmeans(data, 3, 10)
plt.plot(data)
```

Then the centroids will be one dimensional, so they have no `x`

location in that plot, so you could plot them as lines, for example:

```
for c in centroids:
plt.axhline(c)
```

If you want to find the centroids of the x-y pairs where `x = range(len(data))`

and `y = data`

, then you must pass those pairs to the clustering algorithm, like so:

```
xydata = np.column_stack([range(len(data)), data])
centroids, variances= kmeans(xydata, 3, 10)
```

But I doubt this is what you want. Probably, you want random `x`

*and* `y`

values, so try something like:

```
data = np.random.rand(100,2)
centroids, variances = kmeans(data, 3, 10)
```

`data = np.random.rand(100,2)`

then`plot(*data.T, 'ob')`

(btw,`np.random.rand`

returns an array, no need to call`np.array`

on it.) – askewchan Nov 24 '13 at 18:50`data = np.column_stack([x,y])`

– askewchan Dec 12 '13 at 20:43