隐马尔科夫模型(HMM)
模型介绍
HMM模型是由一个“五元组”组成:
StatusSet: 状态值集合
ObservedSet: 观察值集合
TransProbMatrix: 转移概率矩阵
EmitProbMatrix: 发射概率矩阵
InitStatus: 初始状态分布
将HMM应用在分词上,要解决的问题是:参数(ObservedSet, TransProbMatrix, EmitRobMatrix, InitStatus)已知的情况下,求解状态值序列。解决这个问题的最有名的方法是viterbi算法。
参数介绍
1.StatusSet,状态值集合为(B, M, E, S): {B:begin, M:middle, E:end, S:single}。分别代表每个状态代表的是该字在词语中的位置,B代表该字是词语中的起始字,M代表是词语中的中间字,E代表是词语中的结束字,S则代表是单字成词。
2.ObservedSet,观察值集合就是所有汉字,甚至包括标点符号所组成的集合。
3.TransProbMatrix,状态转移概率矩阵的含义就是从状态X转移到状态Y的概率,是一个4×4的矩阵,即{B,E,M,S}×{B,E,M,S}。
4.EmitProbMatrix,发射概率矩阵的每个元素都是一个条件概率,代表P(Observed[i]|Status[j])
5.InitStatus,初始状态概率分布表示句子的第一个字属于{B,E,M,S}这四种状态的概率。
Viterbi算法
Viterbi算法的核心思想就是动态规划实现最短路径,按照Michael Collins教的,核心思想是:
Define a dynamic programming table π(k,u,v),
π(k,u,v) = maximum probability of a tag sequence ending in tags u,v at position k.
For any k ∈ {1…n}: π(k,u,v) = max ( π(k-1,w,u) × q(v|w,u) × e(xk|v) )
完整的Viterbi算法网上有很多资料可以查看,本文主要关注代码的实现。
模型训练
# -*- coding: utf-8 -*-
# 二元隐马尔科夫模型(Bigram HMMs)
# 'trainCorpus.txt_utf8'为人民日报已经人工分词的预料,29万多条句子
import sys
# state_M = 4
# word_N = 0
A_dic = {}
B_dic = {}
Count_dic = {}
Pi_dic = {}
word_set = set()
state_list = ['B', 'M', 'E', 'S']
line_num = -1
INPUT_DATA = "trainCorpus.txt_utf8"
PROB_START = "prob_start.py" # 初始状态概率
PROB_EMIT = "prob_emit.py" # 发射概率
PROB_TRANS = "prob_trans.py" # 转移概率
def init(): # 初始化字典
# global state_M
# global word_N
for state in state_list:
A_dic[state] = {}
for state1 in state_list:
A_dic[state][state1] = 0.0
for state in state_list:
Pi_dic[state] = 0.0
B_dic[state] = {}
Count_dic[state] = 0
def getList(input_str): # 输入词语,输出状态
outpout_str = []
if len(input_str) == 1:
outpout_str.append('S')
elif len(input_str) == 2:
outpout_str = ['B', 'E']
else:
M_num = len(input_str) - 2
M_list = ['M'] * M_num
outpout_str.append('B')
outpout_str.extend(M_list) # 把M_list中的'M'分别添加进去
outpout_str.append('E')
return outpout_str
def Output(): # 输出模型的三个参数:初始概率+转移概率+发射概率
start_fp = open(PROB_START, mode='w',encoding="utf-8")
emit_fp = open(PROB_EMIT, mode='w',encoding="utf-8")
trans_fp = open(PROB_TRANS, mode='w',encoding="utf-8")
print ("len(word_set) = %s " % (len(word_set)))
for key in Pi_dic: # 状态的初始概率
Pi_dic[key] = Pi_dic[key] * 1.0 / line_num
print (Pi_dic,file=start_fp)
for key in A_dic: # 状态转移概率
for key1 in A_dic[key]:
A_dic[key][key1] = A_dic[key][key1] / Count_dic[key]
print (A_dic,file=trans_fp)
for key in B_dic: # 发射概率(状态->词语的条件概率)
for word in B_dic[key]:
B_dic[key][word] = B_dic[key][word] / Count_dic[key]
print (B_dic,file=emit_fp)
start_fp.close()
emit_fp.close()
trans_fp.close()
def main():
ifp = open(INPUT_DATA,'r',encoding="UTF-8")
init()
global word_set # 初始是set()
global line_num # 初始是-1
for line in ifp:
line_num += 1
if line_num % 10000 == 0:
print (line_num)
line = line.strip()
if not line: continue
#line = line.encode("utf-8", "ignore") # 设置为ignore,会忽略非法字符
word_list = []
for i in range(len(line)):
if line[i] == " ": continue
word_list.append(line[i])
word_set = word_set | set(word_list) # 训练预料库中所有字的集合
lineArr = line.split(" ")
line_state = []
for item in lineArr:
line_state.extend(getList(item)) # 一句话对应一行连续的状态
if len(word_list) != len(line_state):
print (sys.stderr, "[line_num = %d][line = %s]" % (line_num, line.endoce("utf-8", 'ignore')))
else:
for i in range(len(line_state)):
if i == 0:
Pi_dic[line_state[0]] += 1 # Pi_dic记录句子第一个字的状态,用于计算初始状态概率
Count_dic[line_state[0]] += 1 # 记录每一个状态的出现次数
else:
A_dic[line_state[i - 1]][line_state[i]] += 1 # 用于计算转移概率
Count_dic[line_state[i]] += 1
if not word_list[i] in B_dic[line_state[i]]:
B_dic[line_state[i]][word_list[i]] = 0.0
else:
B_dic[line_state[i]][word_list[i]] += 1 # 用于计算发射概率
Output()
ifp.close()
if __name__ == "__main__":
main()
测试分词效果
# -*- coding: utf-8 -*-
def load_model(f_name):
ifp = open(f_name, mode='rb')
return eval(ifp.read()) # eval参数是一个字符串, 可以把这个字符串当成表达式来求值,
prob_start = load_model("prob_start.py")
prob_trans = load_model("prob_trans.py")
prob_emit = load_model("prob_emit.py")
def viterbi(obs, states, start_p, trans_p, emit_p): # 维特比算法(一种递归算法)
V = [{}]
path = {}
for y in states: # 初始值
V[0][y] = start_p[y] * emit_p[y].get(obs[0], 0) # 在位置0,以y状态为末尾的状态序列的最大概率
path[y] = [y]
for t in range(1, len(obs)):
V.append({})
newpath = {}
for y in states: # 从y0 -> y状态的递归
(prob, state) = max(
[(V[t - 1][y0] * trans_p[y0].get(y, 0) * emit_p[y].get(obs[t], 0), y0) for y0 in states if
V[t - 1][y0] > 0])
V[t][y] = prob
newpath[y] = path[state] + [y]
path = newpath # 记录状态序列
(prob, state) = max([(V[len(obs) - 1][y], y) for y in states]) # 在最后一个位置,以y状态为末尾的状态序列的最大概率
return (prob, path[state]) # 返回概率和状态序列
def cut(sentence):
prob, pos_list = viterbi(sentence, ('B', 'M', 'E', 'S'), prob_start, prob_trans, prob_emit)
return (prob, pos_list)
if __name__ == "__main__":
test_str = u"新华网驻东京记者报道"
prob, pos_list = cut(test_str)
print (test_str)
print (pos_list)
结果:
新华网驻东京记者报道
['B', 'M', 'E', 'S', 'B', 'E', 'B', 'E', 'B', 'E']
人工分词的预料(trainCorpus.txt_utf8)下载连接
https://pan.baidu.com/s/1geZkMif