A repository documenting the implementation of k-Means clustering in Python. Usage examples can be found in the tests
directory.
The thing that makes this k-means clustering module different from others is that it allows the user to specify the number of dimensions to use for the clustering operation.
For example, given some data where each element is of form
# Each element would actually be a Numpy array, but the following uses lists for readability.
[
[1, 2, 3, 4, 5],
[4, 6, 7, 8, 2],
...
]
specifying ndim=3
will result in only the first three elements of each data point being used for each operation.
This is useful for maintaining data association where it otherwise would be shuffled. An example of this is found in my implementation of image segmentation (segmentation.py
) in this same project.
Other examples of use could be for maintaining data association in object detection elements. Given some
[xmin, ymin, xmax, ymax, conf, label] # [bounding box, conf, label]
we may want to cluster the data solely on bounding box information while also maintaining the confidence intervals for each detection for further processing.
$ python -m pip install kmeans-tjdwill
Specifying the k
value results in a dict[int: NDArray]
where each NDArray
contains the elements within the cluster. The keys of this dict range from 0
to k-1
, allowing the key to also be used to index the corresponding cluster centroid from the centroid array.
Here is an example of the use of the cluster
function:
>>> from kmeans import cluster
>>> import numpy as np
>>> np.random.seed(27) # For reproducible results
>>> data = np.random.random((15, 5)).round(3)
>>> data[0]
array([0.426, 0.815, 0.735, 0.868, 0.383])
>>> # Cluster using only first two dimensions
>>> clusters, centroids = cluster(data, k=3, ndim=2, tolerance=0.001)
>>> centroids
array([[0.9004 , 0.79 ],
[0.361375, 0.580125],
[0.801 , 0.143 ]])
>>> clusters # visually compare centroids with first two elements of each data entry.
{0: array([[0.979, 0.893, 0.21 , 0.742, 0.663],
[0.887, 0.858, 0.749, 0.87 , 0.187],
[0.966, 0.583, 0.092, 0.014, 0.837],
[0.915, 0.705, 0.387, 0.706, 0.923],
[0.755, 0.911, 0.242, 0.976, 0.304]]),
1: array([[0.426, 0.815, 0.735, 0.868, 0.383],
[0.326, 0.373, 0.794, 0.151, 0.17 ],
[0.081, 0.305, 0.783, 0.163, 0.071],
[0.221, 0.726, 0.849, 0.929, 0.736],
[0.477, 0.493, 0.595, 0.076, 0.117],
[0.288, 0.684, 0.52 , 0.877, 0.924],
[0.489, 0.596, 0.264, 0.992, 0.21 ],
[0.583, 0.649, 0.911, 0.122, 0.676]]),
2: array([[0.701, 0.181, 0.599, 0.415, 0.514],
[0.901, 0.105, 0.673, 0.87 , 0.561]])}
- k-means clustering (no side-effects)
- k-means clustering w/ animation
- (2-D & 3-D)
- image segmentation via
kmeans.segmentation.segment_img
function
Using the view_clustering
function
kmeans2D_animate.webm
kmeans3D_animate.webm
Perform image segmentation based on color groups specified by the user.
Two options:
k=4
k=10
k=4
- Python (3.12.1)
- Numpy (1.26.2)
- Matplotlib (3.8.4)
However, no features specific to Python 3.12 were used.