Python基于聚类算法实现密度聚类(DBSCAN)计算【测试可用】

脚本专栏 2024/11/6 佚名

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本文实例讲述了Python基于聚类算法实现密度聚类(DBSCAN)计算。分享给大家供大家参考，具体如下：

算法思想

基于密度的聚类算法从样本密度的角度考察样本之间的可连接性，并基于可连接样本不断扩展聚类簇得到最终结果。

几个必要概念：

ε-邻域：对于样本集中的xj, 它的ε-邻域为样本集中与它距离小于ε的样本所构成的集合。
核心对象：若xj的ε-邻域中至少包含MinPts个样本，则xj为一个核心对象。
密度直达：若xj位于xi的ε-邻域中，且xi为核心对象，则xj由xi密度直达。
密度可达：若样本序列p1, p2, ……, pn。pi+1由pi密度直达，则p1由pn密度可达。

大致思想如下：

1. 初始化核心对象集合T为空，遍历一遍样本集D中所有的样本，计算每个样本点的ε-邻域中包含样本的个数，如果个数大于等于MinPts，则将该样本点加入到核心对象集合中。初始化聚类簇数k = 0，初始化未访问样本集和为P = D。

2. 当T集合中存在样本时执行如下步骤：

2.1记录当前未访问集合P_old = P
2.2从T中随机选一个核心对象o,初始化一个队列Q = [o]
2.3P = P-o(从T中删除o)
2.4当Q中存在样本时执行：
2.4.1取出队列中的首个样本q
2.4.2计算q的ε-邻域中包含样本的个数，如果大于等于MinPts，则令S为q的ε-邻域与P的交集，
Q = Q+S, P = P-S
2.5 k = k + 1,生成聚类簇为Ck = P_old - P
2.6 T = T - Ck

3. 划分为C= {C1, C2, ……, Ck}

Python代码实现

#-*- coding:utf-8 -*-
import math
import numpy as np
import pylab as pl
 #数据集：每三个是一组分别是西瓜的编号，密度，含糖量
data = """
1,0.697,0.46,2,0.774,0.376,3,0.634,0.264,4,0.608,0.318,5,0.556,0.215,
6,0.403,0.237,7,0.481,0.149,8,0.437,0.211,9,0.666,0.091,10,0.243,0.267,
11,0.245,0.057,12,0.343,0.099,13,0.639,0.161,14,0.657,0.198,15,0.36,0.37,
16,0.593,0.042,17,0.719,0.103,18,0.359,0.188,19,0.339,0.241,20,0.282,0.257,
21,0.748,0.232,22,0.714,0.346,23,0.483,0.312,24,0.478,0.437,25,0.525,0.369,
26,0.751,0.489,27,0.532,0.472,28,0.473,0.376,29,0.725,0.445,30,0.446,0.459"""
#数据处理 dataset是30个样本（密度，含糖量）的列表
a = data.split(',')
dataset = [(float(a[i]), float(a[i+1])) for i in range(1, len(a)-1, 3)]
#计算欧几里得距离,a,b分别为两个元组
def dist(a, b):
  return math.sqrt(math.pow(a[0]-b[0], 2)+math.pow(a[1]-b[1], 2))
#算法模型
def DBSCAN(D, e, Minpts):
  #初始化核心对象集合T,聚类个数k,聚类集合C, 未访问集合P,
  T = set(); k = 0; C = []; P = set(D)
  for d in D:
    if len([ i for i in D if dist(d, i) <= e]) >= Minpts:
      T.add(d)
  #开始聚类
  while len(T):
    P_old = P
    o = list(T)[np.random.randint(0, len(T))]
    P = P - set(o)
    Q = []; Q.append(o)
    while len(Q):
      q = Q[0]
      Nq = [i for i in D if dist(q, i) <= e]
      if len(Nq) >= Minpts:
        S = P & set(Nq)
        Q += (list(S))
        P = P - S
      Q.remove(q)
    k += 1
    Ck = list(P_old - P)
    T = T - set(Ck)
    C.append(Ck)
  return C
#画图
def draw(C):
  colValue = ['r', 'y', 'g', 'b', 'c', 'k', 'm']
  for i in range(len(C)):
    coo_X = []  #x坐标列表
    coo_Y = []  #y坐标列表
    for j in range(len(C[i])):
      coo_X.append(C[i][j][0])
      coo_Y.append(C[i][j][1])
    pl.scatter(coo_X, coo_Y, marker='x', color=colValue[i%len(colValue)], label=i)
  pl.legend(loc='upper right')
  pl.show()
C = DBSCAN(dataset, 0.11, 5)
draw(C)

本机测试运行结果图：