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@iandanforth
Last active May 13, 2024 14:00
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A pure python implementation of K-Means clustering. Optional cluster visualization using plot.ly.
#############################################################################
# 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()
@Semnodime
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Semnodime commented Jun 9, 2018

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

@engrhammadmalik
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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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