python实现 模糊C均值聚类算法(Fuzzy-C-Means)-基于iris数据集

# python3模糊C均值聚类算法,数据集为iris,放在和代码同一目录即可。算法原理及步骤参考:https://wenku.baidu.com/view/ee968c00eff9aef8941e06a2.html
import copy
import math
import random
import time
import sys
import matplotlib.pyplot as plt
import matplotlib.animation as animation
import decimal


# 用于初始化隶属度矩阵U
global MAX
MAX = 10000.0
# 用于结束条件
global Epsilon
Epsilon = 0.00000001

def import_data_format_iris(file):
	""" 
	格式化数据,前四列为data,最后一列为cluster_location
	数据地址 http://archive.ics.uci.edu/ml/machine-learning-databases/iris/
	"""
	data = []
	cluster_location =[]
	with open(str(file), 'r') as f:
		for line in f:
			current = line.strip().split(",")
			current_dummy = []
			for j in range(0, len(current)-1):
				current_dummy.append(float(current[j]))
			j += 1 
			if  current[j] == "Iris-setosa\n":
				cluster_location.append(0)
			elif current[j] == "Iris-versicolor\n":
				cluster_location.append(1)
			else:
				cluster_location.append(2)
			data.append(current_dummy)
	print ("加载数据完毕")
	return data , cluster_location

def randomise_data(data):
	"""
	该功能将数据随机化,并保持随机化顺序的记录
	"""
	order = list(range(0, len(data)))
	random.shuffle(order)
	new_data = [[] for i in range(0, len(data))]
	for index in range(0, len(order)):
		new_data[index] = data[order[index]]
	return new_data, order

def de_randomise_data(data, order):
	"""
	此函数将返回数据的原始顺序,将randomise_data()返回的order列表作为参数
	"""
	new_data = [[]for i in range(0, len(data))]
	for index in range(len(order)):
		new_data[order[index]] = data[index]
	return new_data

def print_matrix(list):
	""" 
	以可重复的方式打印矩阵
	"""
	for i in range(0, len(list)):
		print (list[i])

def initialise_U(data, cluster_number):
	"""
	这个函数是隶属度矩阵U的每行加起来都为1. 此处需要一个全局变量MAX.
	"""
	global MAX
	U = []
	for i in range(0, len(data)):
		current = []
		rand_sum = 0.0
		for j in range(0, cluster_number):
			dummy = random.randint(1,int(MAX))
			current.append(dummy)
			rand_sum += dummy
		for j in range(0, cluster_number):
			current[j] = current[j] / rand_sum
		U.append(current)
	return U

def distance(point, center):
	"""
	该函数计算2点之间的距离(作为列表)。我们指欧几里德距离。        闵可夫斯基距离
	"""
	if len(point) != len(center):
		return -1
	dummy = 0.0
	for i in range(0, len(point)):
		dummy += abs(point[i] - center[i]) ** 2
	return math.sqrt(dummy)

def end_conditon(U, U_old):
    """
	结束条件。当U矩阵随着连续迭代停止变化时,触发结束
	"""
    global Epsilon
    for i in range(0, len(U)):
	    for j in range(0, len(U[0])):
		    if abs(U[i][j] - U_old[i][j]) > Epsilon :
			    return False
    return True

def normalise_U(U):
	"""
	在聚类结束时使U模糊化。每个样本的隶属度最大的为1,其余为0
	"""
	for i in range(0, len(U)):
		maximum = max(U[i])
		for j in range(0, len(U[0])):
			if U[i][j] != maximum:
				U[i][j] = 0
			else:
				U[i][j] = 1
	return U

# m的最佳取值范围为[1.5,2.5]
def fuzzy(data, cluster_number, m):
	"""
	这是主函数,它将计算所需的聚类中心,并返回最终的归一化隶属矩阵U.
    参数是:簇数(cluster_number)和隶属度的因子(m)
	"""
	# 初始化隶属度矩阵U
	U = initialise_U(data, cluster_number)
	# print_matrix(U)
	# 循环更新U
	while (True):
		# 创建它的副本,以检查结束条件
		U_old = copy.deepcopy(U)
		# 计算聚类中心
		C = []
		for j in range(0, cluster_number):
			current_cluster_center = []
			for i in range(0, len(data[0])):
				dummy_sum_num = 0.0
				dummy_sum_dum = 0.0
				for k in range(0, len(data)):
    				# 分子
					dummy_sum_num += (U[k][j] ** m) * data[k][i]
					# 分母
					dummy_sum_dum += (U[k][j] ** m)
				# 第i列的聚类中心
				current_cluster_center.append(dummy_sum_num/dummy_sum_dum)
            # 第j簇的所有聚类中心
			C.append(current_cluster_center)

		# 创建一个距离向量, 用于计算U矩阵。
		distance_matrix =[]
		for i in range(0, len(data)):
			current = []
			for j in range(0, cluster_number):
				current.append(distance(data[i], C[j]))
			distance_matrix.append(current)

		# 更新U
		for j in range(0, cluster_number):	
			for i in range(0, len(data)):
				dummy = 0.0
				for k in range(0, cluster_number):
    				# 分母
					dummy += (distance_matrix[i][j ] / distance_matrix[i][k]) ** (2/(m-1))
				U[i][j] = 1 / dummy

		if end_conditon(U, U_old):
			print ("结束聚类")
			break
	print ("标准化 U")
	U = normalise_U(U)
	return U

def checker_iris(final_location):
    """
	和真实的聚类结果进行校验比对
	"""
    right = 0.0
    for k in range(0, 3):
	    checker =[0,0,0]
	    for i in range(0, 50):
		    for j in range(0, len(final_location[0])):
			    if final_location[i + (50*k)][j] == 1:
				    checker[j] += 1
	    right += max(checker)
	    print (right)
    answer =  right / 150 * 100
    return "准确度:" + str(answer) +  "%"

if __name__ == '__main__':
	
	# 加载数据
	data, cluster_location = import_data_format_iris("iris.txt")
	# print_matrix(data)

	# 随机化数据
	data , order = randomise_data(data)
	# print_matrix(data)

	start = time.time()
	# 现在我们有一个名为data的列表,它只是数字
	# 我们还有另一个名为cluster_location的列表,它给出了正确的聚类结果位置
	# 调用模糊C均值函数
	final_location = fuzzy(data , 2 , 2)
 
	# 还原数据
	final_location = de_randomise_data(final_location, order)
	# print_matrix(final_location)

	# 准确度分析
	print (checker_iris(final_location))
	print ("用时:{0}".format(time.time() - start))

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