# K的选择:肘部法则
如果问题中没有指定 的值,可以通过肘部法则这一技术来估计聚类数量。肘部法则会把不同 值的
成本函数值画出来。随着 值的增大,平均畸变程度会减小;每个类包含的样本数会减少,于是样本
离其重心会更近。但是,随着 值继续增大,平均畸变程度的改善效果会不断减低。 值增大过程
中,畸变程度的改善效果下降幅度最大的位置对应的 值就是肘部。
import numpy as np
import matplotlib.pyplot as plt
%matplotlib inline
#随机生成一个实数,范围在(0.5,1.5)之间
cluster1=np.random.uniform(0.5,1.5,(2,10))
cluster2=np.random.uniform(3.5,4.5,(2,10))
#hstack拼接操作
X=np.hstack((cluster1,cluster2)).T
plt.figure()
plt.axis([0,5,0,5])
plt.grid(True)
plt.plot(X[:,0],X[:,1],'k.')
%matplotlib inline
import matplotlib.pyplot as plt
from matplotlib.font_manager import FontProperties
font = FontProperties(fname=r"c:\windows\fonts\msyh.ttc", size=10)
#coding:utf-8
#我们计算K值从1到10对应的平均畸变程度:
from sklearn.cluster import KMeans
#用scipy求解距离
from scipy.spatial.distance import cdist
K=range(1,10)
meandistortions=[]
for k in K:
kmeans=KMeans(n_clusters=k)
kmeans.fit(X)
meandistortions.append(sum(np.min(
cdist(X,kmeans.cluster_centers_,
'euclidean'),axis=1))/X.shape[0])
plt.plot(K,meandistortions,'bx-')
plt.xlabel('k')
plt.ylabel(u'平均畸变程度',fontproperties=font)
plt.title(u'用肘部法则来确定最佳的K值',fontproperties=font)
import numpy as np
x1 = np.array([1, 2, 3, 1, 5, 6, 5, 5, 6, 7, 8, 9, 7, 9])
x2 = np.array([1, 3, 2, 2, 8, 6, 7, 6, 7, 1, 2, 1, 1, 3])
X=np.array(list(zip(x1,x2))).reshape(len(x1),2)
plt.figure()
plt.axis([0,10,0,10])
plt.grid(True)
plt.plot(X[:,0],X[:,1],'k.')
from sklearn.cluster import KMeans
from scipy.spatial.distance import cdist
K=range(1,10)
meandistortions=[]
for k in K:
kmeans=KMeans(n_clusters=k)
kmeans.fit(X)
meandistortions.append(sum(np.min(cdist(
X,kmeans.cluster_centers_,"euclidean"),axis=1))/X.shape[0])
plt.plot(K,meandistortions,'bx-')
plt.xlabel('k')
plt.ylabel(u'平均畸变程度',fontproperties=font)
plt.title(u'用肘部法则来确定最佳的K值',fontproperties=font)
# 聚类效果的评价
#### 轮廓系数(Silhouette Coefficient):s =ba/max(a, b)
import numpy as np
from sklearn.cluster import KMeans
from sklearn import metrics
plt.figure(figsize=(8,10))
plt.subplot(3,2,1)
x1 = np.array([1, 2, 3, 1, 5, 6, 5, 5, 6, 7, 8, 9, 7, 9])
x2 = np.array([1, 3, 2, 2, 8, 6, 7, 6, 7, 1, 2, 1, 1, 3])
X = np.array(list(zip(x1, x2))).reshape(len(x1), 2)
plt.xlim([0,10])
plt.ylim([0,10])
plt.title(u'样本',fontproperties=font)
plt.scatter(x1, x2)
colors = ['b', 'g', 'r', 'c', 'm', 'y', 'k', 'b']
markers = ['o', 's', 'D', 'v', '^', 'p', '*', '+']
tests=[2,3,4,5,8]
subplot_counter=1
for t in tests:
subplot_counter+=1
plt.subplot(3,2,subplot_counter)
kmeans_model=KMeans(n_clusters=t).fit(X)
# print kmeans_model.labels_:每个点对应的标签值
for i,l in enumerate(kmeans_model.labels_):
plt.plot(x1[i],x2[i],color=colors[l],
marker=markers[l],ls='None')
plt.xlim([0,10])
plt.ylim([0,10])
plt.title(u'K = %s, 轮廓系数 = %.03f' %
(t, metrics.silhouette_score
(X, kmeans_model.labels_,metric='euclidean'))
,fontproperties=font)
# 图像向量化
import numpy as np
from sklearn.cluster import KMeans
from sklearn.utils import shuffle
import mahotas as mh
original_img=np.array(mh.imread('tree.bmp'),dtype=np.float64)/255
original_dimensions=tuple(original_img.shape)
width,height,depth=tuple(original_img.shape)
image_flattend=np.reshape(original_img,(width*height,depth))
print image_flattend.shape
image_flattend
输出结果:
(102672L, 3L)
Out[96]:
array([[ 0.55686275, 0.57647059, 0.61960784],
[ 0.68235294, 0.70196078, 0.74117647],
[ 0.72156863, 0.7372549 , 0.78039216],
...,
[ 0.75686275, 0.63529412, 0.46666667],
[ 0.74117647, 0.61568627, 0.44705882],
[ 0.70588235, 0.57647059, 0.40784314]])
然后我们用K-Means算法在随机选择1000个颜色样本中建立64个类。每个类都可能是压缩调色板中的一种颜色
image_array_sample=shuffle(image_flattend,random_state=0)[:1000]
image_array_sample.shape
estimator=KMeans(n_clusters=64,random_state=0)
estimator.fit(image_array_sample)
#之后,我们为原始图片的每个像素进行类的分配
cluster_assignments=estimator.predict(image_flattend)
print cluster_assignments.shape
cluster_assignments输出结果:
(102672L,)
Out[105]:
array([59, 39, 33, ..., 46, 8, 17])
#最后,我们建立通过压缩调色板和类分配结果创建压缩后的图片:
compressed_palette = estimator.cluster_centers_
compressed_img = np.zeros((width, height, compressed_palette.shape[1]))
label_idx = 0
for i in range(width):
for j in range(height):
compressed_img[i][j] = compressed_palette[cluster_assignments[label_idx]]
label_idx += 1
plt.subplot(122)
plt.title('Original Image')
plt.imshow(original_img)
plt.axis('off')
plt.subplot(121)
plt.title('Compressed Image')
plt.imshow(compressed_img)
plt.axis('off')
plt.show()
