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A pure python implementation of K-Means clustering. Optional cluster visualization using plot.ly.
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############################################################################# | |
# Full Imports | |
from __future__ import division | |
import math | |
import random | |
""" | |
This is a pure Python implementation of the K-means Clustering algorithmn. The | |
original can be found here: | |
http://pandoricweb.tumblr.com/post/8646701677/python-implementation-of-the-k-means-clustering | |
I have refactored the code and added comments to aid in readability. | |
After reading through this code you should understand clearly how K-means works. | |
If not, feel free to email me with questions and suggestions. (iandanforth at | |
gmail) | |
This script specifically avoids using numpy or other more obscure libraries. It | |
is meant to be *clear* not fast. | |
I have also added integration with the plot.ly plotting library. So you can see | |
the clusters found by this algorithm. To install run: | |
``` | |
pip install plotly | |
``` | |
This script uses an offline plotting mode and will store and open plots locally. | |
To store and share plots online sign up for a plotly API key at https://plot.ly. | |
""" | |
plotly = False | |
try: | |
import plotly | |
from plotly.graph_objs import Scatter, Scatter3d, Layout | |
except ImportError: | |
print "INFO: Plotly is not installed, plots will not be generated." | |
def main(): | |
# How many points are in our dataset? | |
num_points = 20 | |
# For each of those points how many dimensions do they have? | |
# Note: Plotting will only work in two or three dimensions | |
dimensions = 2 | |
# Bounds for the values of those points in each dimension | |
lower = 0 | |
upper = 200 | |
# The K in k-means. How many clusters do we assume exist? | |
# - Must be less than num_points | |
num_clusters = 3 | |
# When do we say the process has 'converged' and stop updating clusters? | |
cutoff = 0.2 | |
# Generate some points to cluster | |
# Note: If you want to use your own data, set points equal to it here. | |
points = [ | |
makeRandomPoint(dimensions, lower, upper) for i in xrange(num_points) | |
] | |
# Cluster those data! | |
iteration_count = 20 | |
best_clusters = iterative_kmeans( | |
points, | |
num_clusters, | |
cutoff, | |
iteration_count | |
) | |
# Print our best clusters | |
for i, c in enumerate(best_clusters): | |
for p in c.points: | |
print " Cluster: ", i, "\t Point :", p | |
# Display clusters using plotly for 2d data | |
if dimensions in [2, 3] and plotly: | |
print "Plotting points, launching browser ..." | |
plotClusters(best_clusters, dimensions) | |
############################################################################# | |
# K-means Methods | |
def iterative_kmeans(points, num_clusters, cutoff, iteration_count): | |
""" | |
K-means isn't guaranteed to get the best answer the first time. It might | |
get stuck in a "local minimum." | |
Here we run kmeans() *iteration_count* times to increase the chance of | |
getting a good answer. | |
Returns the best set of clusters found. | |
""" | |
print "Running K-means %d times to find best clusters ..." % iteration_count | |
candidate_clusters = [] | |
errors = [] | |
for _ in range(iteration_count): | |
clusters = kmeans(points, num_clusters, cutoff) | |
error = calculateError(clusters) | |
candidate_clusters.append(clusters) | |
errors.append(error) | |
highest_error = max(errors) | |
lowest_error = min(errors) | |
print "Lowest error found: %.2f (Highest: %.2f)" % ( | |
lowest_error, | |
highest_error | |
) | |
ind_of_lowest_error = errors.index(lowest_error) | |
best_clusters = candidate_clusters[ind_of_lowest_error] | |
return best_clusters | |
def kmeans(points, k, cutoff): | |
# Pick out k random points to use as our initial centroids | |
initial_centroids = random.sample(points, k) | |
# Create k clusters using those centroids | |
# Note: Cluster takes lists, so we wrap each point in a list here. | |
clusters = [Cluster([p]) for p in initial_centroids] | |
# Loop through the dataset until the clusters stabilize | |
loopCounter = 0 | |
while True: | |
# Create a list of lists to hold the points in each cluster | |
lists = [[] for _ in clusters] | |
clusterCount = len(clusters) | |
# Start counting loops | |
loopCounter += 1 | |
# For every point in the dataset ... | |
for p in points: | |
# Get the distance between that point and the centroid of the first | |
# cluster. | |
smallest_distance = getDistance(p, clusters[0].centroid) | |
# Set the cluster this point belongs to | |
clusterIndex = 0 | |
# For the remainder of the clusters ... | |
for i in range(1, clusterCount): | |
# calculate the distance of that point to each other cluster's | |
# centroid. | |
distance = getDistance(p, clusters[i].centroid) | |
# If it's closer to that cluster's centroid update what we | |
# think the smallest distance is | |
if distance < smallest_distance: | |
smallest_distance = distance | |
clusterIndex = i | |
# After finding the cluster the smallest distance away | |
# set the point to belong to that cluster | |
lists[clusterIndex].append(p) | |
# Set our biggest_shift to zero for this iteration | |
biggest_shift = 0.0 | |
# For each cluster ... | |
for i in range(clusterCount): | |
# Calculate how far the centroid moved in this iteration | |
shift = clusters[i].update(lists[i]) | |
# Keep track of the largest move from all cluster centroid updates | |
biggest_shift = max(biggest_shift, shift) | |
# Remove empty clusters | |
clusters = [c for c in clusters if len(c.points) != 0] | |
# If the centroids have stopped moving much, say we're done! | |
if biggest_shift < cutoff: | |
print "Converged after %s iterations" % loopCounter | |
break | |
return clusters | |
############################################################################# | |
# Classes | |
class Point(object): | |
''' | |
A point in n dimensional space | |
''' | |
def __init__(self, coords): | |
''' | |
coords - A list of values, one per dimension | |
''' | |
self.coords = coords | |
self.n = len(coords) | |
def __repr__(self): | |
return str(self.coords) | |
class Cluster(object): | |
''' | |
A set of points and their centroid | |
''' | |
def __init__(self, points): | |
''' | |
points - A list of point objects | |
''' | |
if len(points) == 0: | |
raise Exception("ERROR: empty cluster") | |
# The points that belong to this cluster | |
self.points = points | |
# The dimensionality of the points in this cluster | |
self.n = points[0].n | |
# Assert that all points are of the same dimensionality | |
for p in points: | |
if p.n != self.n: | |
raise Exception("ERROR: inconsistent dimensions") | |
# Set up the initial centroid (this is usually based off one point) | |
self.centroid = self.calculateCentroid() | |
def __repr__(self): | |
''' | |
String representation of this object | |
''' | |
return str(self.points) | |
def update(self, points): | |
''' | |
Returns the distance between the previous centroid and the new after | |
recalculating and storing the new centroid. | |
Note: Initially we expect centroids to shift around a lot and then | |
gradually settle down. | |
''' | |
old_centroid = self.centroid | |
self.points = points | |
# Return early if we have no points, this cluster will get | |
# cleaned up (removed) in the outer loop. | |
if len(self.points) == 0: | |
return 0 | |
self.centroid = self.calculateCentroid() | |
shift = getDistance(old_centroid, self.centroid) | |
return shift | |
def calculateCentroid(self): | |
''' | |
Finds a virtual center point for a group of n-dimensional points | |
''' | |
numPoints = len(self.points) | |
# Get a list of all coordinates in this cluster | |
coords = [p.coords for p in self.points] | |
# Reformat that so all x's are together, all y'z etc. | |
unzipped = zip(*coords) | |
# Calculate the mean for each dimension | |
centroid_coords = [math.fsum(dList)/numPoints for dList in unzipped] | |
return Point(centroid_coords) | |
def getTotalDistance(self): | |
''' | |
Return the sum of all squared Euclidean distances between each point in | |
the cluster and the cluster's centroid. | |
''' | |
sumOfDistances = 0.0 | |
for p in self.points: | |
sumOfDistances += getDistance(p, self.centroid) | |
return sumOfDistances | |
############################################################################# | |
# Helper Methods | |
def getDistance(a, b): | |
''' | |
Squared Euclidean distance between two n-dimensional points. | |
https://en.wikipedia.org/wiki/Euclidean_distance#n_dimensions | |
Note: This can be very slow and does not scale well | |
''' | |
if a.n != b.n: | |
raise Exception("ERROR: non comparable points") | |
accumulatedDifference = 0.0 | |
for i in range(a.n): | |
squareDifference = pow((a.coords[i]-b.coords[i]), 2) | |
accumulatedDifference += squareDifference | |
return accumulatedDifference | |
def makeRandomPoint(n, lower, upper): | |
''' | |
Returns a Point object with n dimensions and values between lower and | |
upper in each of those dimensions | |
''' | |
p = Point([random.uniform(lower, upper) for _ in range(n)]) | |
return p | |
def calculateError(clusters): | |
''' | |
Return the average squared distance between each point and its cluster | |
centroid. | |
This is also known as the "distortion cost." | |
''' | |
accumulatedDistances = 0 | |
num_points = 0 | |
for cluster in clusters: | |
num_points += len(cluster.points) | |
accumulatedDistances += cluster.getTotalDistance() | |
error = accumulatedDistances / num_points | |
return error | |
def plotClusters(data, dimensions): | |
''' | |
This uses the plotly offline mode to create a local HTML file. | |
This should open your default web browser. | |
''' | |
if dimensions not in [2, 3]: | |
raise Exception("Plots are only available for 2 and 3 dimensional data") | |
# Convert data into plotly format. | |
traceList = [] | |
for i, c in enumerate(data): | |
# Get a list of x,y coordinates for the points in this cluster. | |
cluster_data = [] | |
for point in c.points: | |
cluster_data.append(point.coords) | |
trace = {} | |
centroid = {} | |
if dimensions == 2: | |
# Convert our list of x,y's into an x list and a y list. | |
trace['x'], trace['y'] = zip(*cluster_data) | |
trace['mode'] = 'markers' | |
trace['marker'] = {} | |
trace['marker']['symbol'] = i | |
trace['marker']['size'] = 12 | |
trace['name'] = "Cluster " + str(i) | |
traceList.append(Scatter(**trace)) | |
# Centroid (A trace of length 1) | |
centroid['x'] = [c.centroid.coords[0]] | |
centroid['y'] = [c.centroid.coords[1]] | |
centroid['mode'] = 'markers' | |
centroid['marker'] = {} | |
centroid['marker']['symbol'] = i | |
centroid['marker']['color'] = 'rgb(200,10,10)' | |
centroid['name'] = "Centroid " + str(i) | |
traceList.append(Scatter(**centroid)) | |
else: | |
symbols = [ | |
"circle", | |
"square", | |
"diamond", | |
"circle-open", | |
"square-open", | |
"diamond-open", | |
"cross", "x" | |
] | |
symbol_count = len(symbols) | |
if i > symbol_count: | |
print "Warning: Not enough marker symbols to go around" | |
# Convert our list of x,y,z's separate lists. | |
trace['x'], trace['y'], trace['z'] = zip(*cluster_data) | |
trace['mode'] = 'markers' | |
trace['marker'] = {} | |
trace['marker']['symbol'] = symbols[i] | |
trace['marker']['size'] = 12 | |
trace['name'] = "Cluster " + str(i) | |
traceList.append(Scatter3d(**trace)) | |
# Centroid (A trace of length 1) | |
centroid['x'] = [c.centroid.coords[0]] | |
centroid['y'] = [c.centroid.coords[1]] | |
centroid['z'] = [c.centroid.coords[2]] | |
centroid['mode'] = 'markers' | |
centroid['marker'] = {} | |
centroid['marker']['symbol'] = symbols[i] | |
centroid['marker']['color'] = 'rgb(200,10,10)' | |
centroid['name'] = "Centroid " + str(i) | |
traceList.append(Scatter3d(**centroid)) | |
title = "K-means clustering with %s clusters" % str(len(data)) | |
plotly.offline.plot({ | |
"data": traceList, | |
"layout": Layout(title=title) | |
}) | |
if __name__ == "__main__": | |
main() |
Thanks author for the code.i am very new to the python coding,ML. could someone pls guide me can i use this code with my human pedestrian data for step detection.looking for the kind response. Thanks
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As I am not aware of any python3 compatible fork I quickly rewrote the code to work under python3 and obey the PEP rules.
https://gist.github.com/Semnodime/0f90a0c2c1cba55141cd5e5e630f3b8c