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完成Kmeans算法完成聚类
要求: 1、依据算法流程,手动完成Kmeans算法; 2、调用sklearn中聚类算法,对给定数据集进行聚类分析; 3、比照上述2中Kmeans算法的聚类作用。
读取文件
def loadFile(path):
dataList = []
#翻开文件:以二进制读形式、utf-8格局的编码方法 翻开
fr = open(path,"r",encoding='UTF-8')
record = fr.read()
fr.close
#按照行转化为一维表即包括各行作为元素的列表,分隔符有'\r', '\r\n', \n'
recordList = record.splitlines()
#逐行遍历:行内字段按'\t'分隔符分隔,转化为列表
for line in recordList:
if line.strip():
dataList .append(list(map(float, line.split('\t'))))
#回来转化后的矩阵
recordmat = np.mat(dataList )
return recordmat
手动完成Kmeans算法
def kMeans(dataset, k):
m = np.shape(dataset)[0]
ClustDist = np.mat(np.zeros((m, 2)))
cents = randCents(dataset, k)
clusterChanged = True
# 循环迭代,得到最近的聚类中心
while clusterChanged:
clusterChanged = False
for i in range(m):
DistList = [distEclud(dataset[i, :], cents[jk,:]) for jk in range(k)]
minDist = min(DistList)
minIndex = DistList.index(minDist)
if ClustDist[i, 0] != minIndex:
clusterChanged = True
ClustDist[i, :] = minIndex, minDist
# 更新聚类
for cent in range(k):
ptsInClust = dataset[np.nonzero(ClustDist[:, 0].A == cent)[0]]
# 更新聚类中心cents,axis=0按列求均值
cents[cent, :] = np.mean(ptsInClust, axis=0)
# 回来聚类中心和聚类分配矩阵
return cents, ClustDist
处理数据
path_file = "TESTDATA.TXT"
recordMat = loadFile(path_file)
k = 4
cents, distMat = kMeans(recordMat, k)
制作数据散点图
plt.subplot(311)
plt.grid(True)# 生成网格
for indx in range(len(distMat)):
if distMat[indx, 0] == 0:
plt.scatter(recordMat[indx, 0], recordMat[indx, 1], c='red', marker='o')
if distMat[indx, 0] == 1:
plt.scatter(recordMat[indx, 0], recordMat[indx, 1], c='blue', marker='o')
if distMat[indx, 0] == 2:
plt.scatter(recordMat[indx, 0], recordMat[indx, 1], c='cyan', marker='o')
if distMat[indx, 0] == 3:
plt.scatter(recordMat[indx, 0], recordMat[indx, 1], c='green', marker='o')
#if distMat[indx, 0] == 4:
#plt.scatter(recordMat[indx, 0], recordMat[indx, 1], c='black', marker='o')
制作聚类中心
x = [cents[i,0] for i in range(k)]
y = [cents[i,1] for i in range(k)]
plt.scatter(x, y, s = 80, c='yellow', marker='o')
plt.title('Kmeans')
调用sklearn中聚类算法
from sklearn.cluster import KMeans
X = np.array(recordMat) # 生成初始聚类数据
#kmeans_model = KMeans(n_clusters=k, init='k-means++') # 聚类模型
kmeans_model = KMeans(n_clusters=k, init='random') # 聚类模型
kmeans_model.fit(X) # 练习聚类模型
制作k-Means聚类成果
# plt.figure()# 创建窗口
plt.subplot(312)
plt.axis([np.min(X[:,0])-1, np.max(X[:,0]+1), np.min(X[:,1])-1, np.max(X[:,1])+1])# 坐标轴
plt.grid(True)# 生成网格
colors = ['r', 'g', 'b','c'] # 聚类色彩
markers = ['o', 's', 'D', '+'] # 聚类标志
for i, l in enumerate(kmeans_model.labels_):
plt.plot(X[i][0], X[i][1], color=colors[l],marker=markers[l],ls='None')
plt.title('K = %s,random' %(k))
比照作用:
整合代码:
import numpy as np
import matplotlib.pyplot as plt
from sklearn.cluster import KMeans
def loadFile(path):
dataList = []
#翻开文件:以二进制读形式、utf-8格局的编码方法 翻开
fr = open(path,"r",encoding='UTF-8')
record = fr.read()
fr.close
#按照行转化为一维表即包括各行作为元素的列表,分隔符有'\r', '\r\n', \n'
recordList = record.splitlines()
#逐行遍历:行内字段按'\t'分隔符分隔,转化为列表
for line in recordList:
if line.strip():
dataList .append(list(map(float, line.split('\t'))))
#回来转化后的矩阵
recordmat = np.mat(dataList )
return recordmat
def distEclud(vecA, vecB):
return np.linalg.norm(vecA-vecB, ord=2)
def randCents(dataSet, k):
n = np.shape(dataSet)[1]
cents = np.mat(np.zeros((k,n)))
for j in range(n):
#质心必须在数据集范围内,也就是在min到max之间
minCol = min(dataSet[:,j])
maxCol = max(dataSet[:,j])
#利用随机函数生成0到1.0之间的随机数
cents [:,j] = np.mat(minCol + float(maxCol - minCol) * np.random.rand(k,1))
return cents
def kMeans(dataset, k):
m = np.shape(dataset)[0]
ClustDist = np.mat(np.zeros((m, 2)))
cents = randCents(dataset, k)
clusterChanged = True
# 循环迭代,得到最近的聚类中心
while clusterChanged:
clusterChanged = False
for i in range(m):
DistList = [distEclud(dataset[i, :], cents[jk,:]) for jk in range(k)]
minDist = min(DistList)
minIndex = DistList.index(minDist)
if ClustDist[i, 0] != minIndex:
clusterChanged = True
ClustDist[i, :] = minIndex, minDist
# 更新聚类
for cent in range(k):
ptsInClust = dataset[np.nonzero(ClustDist[:, 0].A == cent)[0]]
# 更新聚类中心cents,axis=0按列求均值
cents[cent, :] = np.mean(ptsInClust, axis=0)
# 回来聚类中心和聚类分配矩阵
return cents, ClustDist
path_file = "TESTDATA.TXT"
recordMat = loadFile(path_file)
k = 4
cents, distMat = kMeans(recordMat, k)
# 制作数据散点图
plt.subplot(311)
plt.grid(True)# 生成网格
for indx in range(len(distMat)):
if distMat[indx, 0] == 0:
plt.scatter(recordMat[indx, 0], recordMat[indx, 1], c='red', marker='o')
if distMat[indx, 0] == 1:
plt.scatter(recordMat[indx, 0], recordMat[indx, 1], c='blue', marker='o')
if distMat[indx, 0] == 2:
plt.scatter(recordMat[indx, 0], recordMat[indx, 1], c='cyan', marker='o')
if distMat[indx, 0] == 3:
plt.scatter(recordMat[indx, 0], recordMat[indx, 1], c='green', marker='o')
#if distMat[indx, 0] == 4:
#plt.scatter(recordMat[indx, 0], recordMat[indx, 1], c='black', marker='o')
# 制作聚类中心
x = [cents[i,0] for i in range(k)]
y = [cents[i,1] for i in range(k)]
plt.scatter(x, y, s = 80, c='yellow', marker='o')
plt.title('Kmeans')
X = np.array(recordMat) # 生成初始聚类数据
# plt.figure()# 创建窗口
plt.subplot(312)
plt.axis([np.min(X[:,0])-1, np.max(X[:,0]+1), np.min(X[:,1])-1, np.max(X[:,1])+1])# 坐标轴
plt.grid(True)# 生成网格
colors = ['r', 'g', 'b','c'] # 聚类色彩
markers = ['o', 's', 'D', '+'] # 聚类标志
#kmeans_model = KMeans(n_clusters=k, init='k-means++') # 聚类模型
kmeans_model = KMeans(n_clusters=k, init='random') # 聚类模型
kmeans_model.fit(X) # 练习聚类模型
# 制作k-Means聚类成果
for i, l in enumerate(kmeans_model.labels_):
plt.plot(X[i][0], X[i][1], color=colors[l],marker=markers[l],ls='None')
plt.title('K = %s,random' %(k))
X = np.array(recordMat) # 生成初始聚类数据
# plt.figure()# 创建窗口
plt.subplot(313)
plt.axis([np.min(X[:,0])-1, np.max(X[:,0]+1), np.min(X[:,1])-1, np.max(X[:,1])+1])# 坐标轴
plt.grid(True)# 生成网格
colors = ['r', 'g', 'b','c'] # 聚类色彩
markers = ['o', 's', 'D', '+'] # 聚类标志
kmeans_model = KMeans(n_clusters=k, init='k-means++') # 聚类模型
# kmeans_model = KMeans(n_clusters=k, init='random') # 聚类模型
kmeans_model.fit(X) # 练习聚类模型
# 制作k-Means聚类成果
for i, l in enumerate(kmeans_model.labels_):
plt.plot(X[i][0], X[i][1], color=colors[l],marker=markers[l],ls='None')
plt.title('K = %s,k-means++' %(k))
plt.show()
