import numpy as np x = np.random.randint(1,100,[20,1]) y = np.zeros(20) k = 3 def initcenter(x,k): return x[:k] kc = initcenter(x,k) kc def nearest(kc,i): d=(abs(kc-i)) w=np.where(d==np.min(d)) return w[0][0] kc = initcenter(x,k) nearest(kc,56) def xclassify(x,y,kc): for i in range(x.shape[0]): y[i] = nearest(kc,x[i]) return y kc = initcenter(x,k) y = xclassify(x,y,kc) print(kc,y) def kcmean(x,y,kc,k): l = list(kc) flag = False for c in range(k): m = np.where(y == c) n = np.mean(x[m]) if l[c] != n: l[c] = n flag = True print(l,flag) return (np.array(l),flag) kc = initcenter(x,k) flag = True k = 3 while flag: y = xclassify(x,y,kc) kc,flag = kcmean(x,y,kc,k)
运行结果
二.鸢尾花花瓣长度数据做聚类并用散点图显示
import numpy as np from sklearn.datasets import load_iris iris = load_iris() x = iris.data[:,1] y = np.zeros(150) def initcenter(x,k): #初始聚类中心数组 return x[0:k].reshape(k) def nearest(kc,i): #数组中的值,与聚类中心最小距离所在类别的索引号 d = (abs(kc-i)) w = np.where(d == np.min(d)) return w[0][0] def xclassify(x,y,kc): for i in range(x.shape[0]): #对数组的每个值进行分类,shape[0]读取矩阵第一维度的长度 y[i] = nearest(kc,x[i]) return y def kcmean(x,y,kc,k): #计算各聚类新均值 l = list(kc) flag = False for c in range(k): print(c) m = np.where(y == c) n=np.mean(x[m]) if l[c] != n: l[c] = n flag = True #聚类中心发生变化 print(l,flag) return (np.array(l),flag) k = 3 kc = initcenter(x,k) flag = True print(x,y,kc,flag) #判断聚类中心和目标函数的值是否发生改变,若不变,则输出结果,若改变,则返回2 while flag: y = xclassify(x,y,kc) kc, flag = kcmean(x,y,kc,k) print(y,kc,type(kc)) print(x,y) import matplotlib.pyplot as plt plt.scatter(x,x,c=y,s=50,cmap="rainbow"); plt.show()
运行结果
