python kmeans聚类简单介绍和实现代码_Python

python kmeans聚类简单介绍和实现代码

2021-01-17 00:03Jason____zhou Python

这篇文章主要为大家详细介绍了python kmeans聚类简单介绍和实现代码，具有一定的参考价值，感兴趣的小伙伴们可以参考一下

一、k均值聚类的简单介绍

假设样本分为c类，每个类均存在一个中心点，通过随机生成c个中心点进行迭代，计算每个样本点到类中心的距离（可以自定义、常用的是欧式距离）

将该样本点归入到最短距离所在的类，重新计算聚类中心，进行下次的重新划分样本，最终类中心不改变时，聚类完成

二、伪代码

三、python代码实现

									#!/usr/bin/env python 

									# coding=utf-8 

									import numpy as np 

									import random 

									import matplotlib.pyplot as plt 

									#data:numpy.array dataset 

									#k the number of cluster 

									def k_means(data,k): 

									  #random generate cluster_center 

									  sample_num=data.shape[0] 

									  center_index=random.sample(range(sample_num),k) 

									  cluster_cen=data[center_index,:] 

									  is_change=1

									  cat=np.zeros(sample_num) 

									  while is_change: 

									    is_change=0

									    for i in range(sample_num): 

									      min_distance=100000

									      min_index=0

									      for j in range(k): 

									        sub_data=data[i,:]-cluster_cen[j,:] 

									        distance=np.inner(sub_data,sub_data) 

									        if distance<min_distance: 

									          min_distance=distance 

									          min_index=j+1

									      if cat[i]!=min_index: 

									        is_change=1

									        cat[i]=min_index 

									    for j in range(k): 

									      cluster_cen[j]=np.mean(data[cat==(j+1)],axis=0) 

									  return cat,cluster_cen 

									if __name__=='__main__': 

									  #generate data 

									  cov=[[1,0],[0,1]] 

									  mean1=[1,-1] 

									  x1=np.random.multivariate_normal(mean1,cov,200) 

									  mean2=[5.5,-4.5] 

									  x2=np.random.multivariate_normal(mean2,cov,200) 

									  mean3=[1,4] 

									  x3=np.random.multivariate_normal(mean3,cov,200) 

									  mean4=[6,4.5] 

									  x4=np.random.multivariate_normal(mean4,cov,200) 

									  mean5=[9,0.0] 

									  x5=np.random.multivariate_normal(mean5,cov,200) 

									  X=np.vstack((x1,x2,x3,x4,x5)) 

									  #data distribution 

									  fig1=plt.figure(1) 

									  p1=plt.scatter(x1[:,0],x1[:,1],marker='o',color='r',label='x1') 

									  p2=plt.scatter(x2[:,0],x2[:,1],marker='+',color='m',label='x2') 

									  p3=plt.scatter(x3[:,0],x3[:,1],marker='x',color='b',label='x3') 

									  p4=plt.scatter(x4[:,0],x4[:,1],marker='*',color='g',label='x4') 

									  p5=plt.scatter(x5[:,0],x4[:,1],marker='+',color='y',label='x5') 

									  plt.title('original data') 

									  plt.legend(loc='upper right') 

									  cat,cluster_cen=k_means(X,5)    

									  print 'the number of cluster 1:',sum(cat==1) 

									  print 'the number of cluster 2:',sum(cat==2) 

									  print 'the number of cluster 3:',sum(cat==3) 

									  print 'the number of cluster 4:',sum(cat==4) 

									  print 'the number of cluster 5:',sum(cat==5) 

									  fig2=plt.figure(2) 

									  for i,m,lo,label in zip(range(5),['o','+','x','*','+'],['r','m','b','g','y'],['x1','x2','x3','x4','x5']): 

									    p=plt.scatter(X[cat==(i+1),0],X[cat==(i+1),1],marker=m,color=lo,label=label) 

									  plt.legend(loc='upper right') 

									  plt.title('the clustering result') 

									  plt.show()