隐马尔可夫模型学习小记——forward算法+viterbi算法+forward-backward算法(Baum-welch算法)...

网上关于HMM的学习资料、博客有很多,基本都是左边摘抄一点,右边摘抄一点,这里一个图,那里一个图,公式中有的变量说不清道不明,学起来很费劲。

经过浏览几篇博文(其实有的地方写的也比较乱),在7张4开的草稿纸上写公式、单步跟踪程序,终于还是搞清楚了HMM的原理。 

HMM学习过程:

1、搜索相关博客:

隐马尔可夫模型[博客](图示比较详细,前部分还可以,后部分公式有点乱):http://www.leexiang.com/hidden-markov-model

HMM简介、forward算法和viterbi算法[博客](含源码,算法描述不是很清晰,但是有源码可看)http://www.cnblogs.com/zhangchaoyang/articles/2219571.html

forward-backward算法[博客](含源码,算法描述不是很清晰,但是有源码可看):http://www.cnblogs.com/zhangchaoyang/articles/2220398.html

隐马尔科夫模型PPT—刘秉权[百度文库](算法流程、公式、参数都比较详细,有理论基础之后是很好的总结资源,但是没有具体例子,无基础的同学学习起来不是很形象。):http://wenku.baidu.com/view/2f0d944769eae009581bec04.html

----其他代码资源(没有理论基础,只看代码很难看懂HMM的原理)---

UMDHMM的C语言实现:http://www.kanungo.com/software/umdhmm-v1.02.zip

GitHub上一个UMDHMM的Python实现:https://github.com/dkyang/UMDHMM-python

2、根据隐马尔科夫模型PPT—刘秉权[百度文库],在5张4开草稿纸上把HMM流程顺一遍,下边是整理的笔记:

隐马尔可夫模型学习小记——forward算法+viterbi算法+forward-backward算法(Baum-welch算法)..._第1张图片

 隐马尔可夫模型学习小记——forward算法+viterbi算法+forward-backward算法(Baum-welch算法)..._第2张图片

隐马尔可夫模型学习小记——forward算法+viterbi算法+forward-backward算法(Baum-welch算法)..._第3张图片

隐马尔可夫模型学习小记——forward算法+viterbi算法+forward-backward算法(Baum-welch算法)..._第4张图片

隐马尔可夫模型学习小记——forward算法+viterbi算法+forward-backward算法(Baum-welch算法)..._第5张图片

HMM三个算法的作用:

  forward算法:(评估)给定一HMM模型,计算一观察序列O1O2...OLEN出现的概率。

  viterbi算法:(解码)给定一HMM模型,计算一观察序列O1O2...OLEN对应的最可能的隐藏序列H1H2...HLEN及该隐藏序列出现的概率。

  forward-backward算法:(学习)给定一观察序列O1O2...OLEN,求解能够拟合这个序列的HMM模型。

HMM三个算法之间的关系:

forward算法中的forward变量就是forward-backforward算法中的forward变量,而backward变量与forward变量是类似的;

forward-backward算法是为了通过类似最大似然估计的方法找到局部最优的模型参数,在迭代过程中forward变量和backward变量起了很大作用;

viterbi算法和forward算法很相似,只是forward算法迭代过程需要的是sum,viterbi算法迭代过程需要的是max,而且viterbi算法除了输出概率,还要用逆推过程求解路径;

当用forwar-backward算法求解出模型参数之后,用户给出一个观察序列,用viterbi算法就能求出最可能的隐藏序列以及概率了。

 

首先是forward算法的Python实现:

复制代码
#-*-coding:utf-8-*-
__author__ = 'ZhangHe'
def forward(N,M,A,B,P,observed):
    p = 0.0
    #观察到的状态数目
    LEN = len(observed)
    #中间概率LEN*M
    Q = [([0]*N) for i in range(LEN)]
    #第一个观察到的状态,状态的初始概率乘上隐藏状态到观察状态的条件概率。
    for j in range(N):
        Q[0][j] = P[j]*B[j][observation.index(observed[0])]
    #第一个之后的状态,首先从前一天的每个状态,转移到当前状态的概率求和,然后乘上隐藏状态到观察状态的条件概率。
    for i in range(1,LEN):
        for j in range(N):
            sum = 0.0
            for k in range(N):
                sum += Q[i-1][k]*A[k][j]
            Q[i][j] = sum * B[j][observation.index(observed[i])]
    for i in range(N):
        p += Q[LEN-1][i]
    return p
# 3 种隐藏层状态:sun cloud rain
hidden = []
hidden.append('sun')
hidden.append('cloud')
hidden.append('rain')
N = len(hidden)
# 4 种观察层状态:dry dryish damp soggy
observation = []
observation.append('dry')
observation.append('damp')
observation.append('soggy')
M = len(observation)
# 初始状态矩阵(1*N第一天是sun,cloud,rain的概率)
P = (0.3,0.3,0.4)
# 状态转移矩阵A(N*N 隐藏层状态之间互相转变的概率)
A=((0.2,0.3,0.5),(0.1,0.5,0.4),(0.6,0.1,0.3))
# 混淆矩阵B(N*M 隐藏层状态对应的观察层状态的概率)
B=((0.1,0.5,0.4),(0.2,0.4,0.4),(0.3,0.6,0.1))
#假设观察到一组序列为observed,输出HMM模型(N,M,A,B,P)产生观察序列observed的概率
observed = ['dry']
print forward(N,M,A,B,P,observed)
observed = ['damp']
print forward(N,M,A,B,P,observed)
observed = ['dry','damp']
print forward(N,M,A,B,P,observed)
observed = ['dry','damp','soggy']
print forward(N,M,A,B,P,observed)
复制代码

输出结果:

0.21
0.51
0.1074
0.030162

其中前两个结果和手工计算的一样;

后两个结果没有手工计算,但是在调试程序过程中单步跟踪运行代码,运行过程与手工计算过程相同。

然后是Viterbi算法的Python实现:

复制代码
def viterbi(N,M,A,B,P,hidden,observed):
    sta = []
    LEN = len(observed)
    Q = [([0]*N) for i in range(LEN)]
    path = [([0]*N) for i in range(LEN)]
    #第一天计算,状态的初始概率*隐藏状态到观察状态的条件概率
    for j in range(N):
        Q[0][j]=P[j]*B[j][observation.index(observed[0])]
        path[0][j] = -1
    # 第一天以后的计算
    # 前一天的每个状态转移到当前状态的概率最大值
    # *
    # 隐藏状态到观察状态的条件概率
    for i in range(1,LEN):
        for j in range(N):
            max = 0.0
            index = 0
            for k in range(N):
                if(Q[i-1][k]*A[k][j] > max):
                    max = Q[i-1][k]*A[k][j]
                    index = k
            Q[i][j] = max * B[j][observation.index(observed[i])]
            path[i][j] = index
    #找到最后一天天气呈现哪种观察状态的概率最大
    max = 0.0
    idx = 0
    for i in range(N):
        if(Q[LEN-1][i]>max):
            max = Q[LEN-1][i]
            idx = i
    print "最可能隐藏序列的概率:"+str(max)
    sta.append(hidden[idx])
    #逆推回去找到每天出现哪个隐藏状态的概率最大
    for i in range(LEN-1,0,-1):
        idx = path[i][idx]
        sta.append(hidden[idx])
    sta.reverse()
    return sta;
# 3 种隐藏层状态:sun cloud rain
hidden = []
hidden.append('sun')
hidden.append('cloud')
hidden.append('rain')
N = len(hidden)
# 4 种观察层状态:dry dryish damp soggy
observation = []
observation.append('dry')
observation.append('damp')
observation.append('soggy')
M = len(observation)
# 初始状态矩阵(1*N第一天是sun,cloud,rain的概率)
P = (0.3,0.3,0.4)
# 状态转移矩阵A(N*N 隐藏层状态之间互相转变的概率)
A=((0.2,0.3,0.5),(0.1,0.5,0.4),(0.6,0.1,0.3))
# 混淆矩阵B(N*M 隐藏层状态对应的观察层状态的概率)
B=((0.1,0.5,0.4),(0.2,0.4,0.4),(0.3,0.6,0.1))
#假设观察到一组序列为observed,输出HMM模型(N,M,A,B,P)产生观察序列observed的概率
observed = ['dry','damp','soggy']
print viterbi(N,M,A,B,P,hidden,observed)
复制代码

输出:

最可能隐藏序列的概率:0.005184
['rain', 'rain', 'sun']

 GITHUB上一个Python实现的完整HMM:

复制代码
import numpy as np

DELTA = 0.001

class HMM:


    def __init__(self, pi, A, B):
        self.pi = pi
        self.A = A
        self.B = B
        self.M = B.shape[1]
        self.N = A.shape[0]
        
    def forward(self,obs):
        T = len(obs)
        N = self.N
        
        alpha = np.zeros([N,T])
        alpha[:,0] = self.pi[:] * self.B[:,obs[0]-1]                                                                                                      
    
        for t in xrange(1,T):
            for n in xrange(0,N):
                alpha[n,t] = np.sum(alpha[:,t-1] * self.A[:,n]) * self.B[n,obs[t]-1]
                     
        prob = np.sum(alpha[:,T-1])
        return prob, alpha
        
    def forward_with_scale(self, obs):
        """see scaling chapter in "A tutorial on hidden Markov models and 
        selected applications in speech recognition." 
        """
        T = len(obs)
        N = self.N
        alpha = np.zeros([N,T])
        scale = np.zeros(T)

        alpha[:,0] = self.pi[:] * self.B[:,obs[0]-1]
        scale[0] = np.sum(alpha[:,0])
        alpha[:,0] /= scale[0]

        for t in xrange(1,T):
            for n in xrange(0,N):
                alpha[n,t] = np.sum(alpha[:,t-1] * self.A[:,n]) * self.B[n,obs[t]-1]
            scale[t] = np.sum(alpha[:,t])
            alpha[:,t] /= scale[t]

        logprob = np.sum(np.log(scale[:]))
        return logprob, alpha, scale    
        
    def backward(self, obs):
        T = len(obs)
        N = self.N
        beta = np.zeros([N,T])
        
        beta[:,T-1] = 1
        for t in reversed(xrange(0,T-1)):
            for n in xrange(0,N):
                beta[n,t] = np.sum(self.B[:,obs[t+1]-1] * self.A[n,:] * beta[:,t+1])
                
        prob = np.sum(beta[:,0])
        return prob, beta

    def backward_with_scale(self, obs, scale):
        T = len(obs)
        N = self.N
        beta = np.zeros([N,T])

        beta[:,T-1] = 1 / scale[T-1]
        for t in reversed(xrange(0,T-1)):
            for n in xrange(0,N):
                beta[n,t] = np.sum(self.B[:,obs[t+1]-1] * self.A[n,:] * beta[:,t+1])
                beta[n,t] /= scale[t]
        
        return beta

    def viterbi(self, obs):
        T = len(obs)
        N = self.N
        psi = np.zeros([N,T]) # reverse pointer
        delta = np.zeros([N,T])
        q = np.zeros(T)
        temp = np.zeros(N)        
        
        delta[:,0] = self.pi[:] * self.B[:,obs[0]-1]    
        
        for t in xrange(1,T):
            for n in xrange(0,N):
                temp = delta[:,t-1] * self.A[:,n]    
                max_ind = argmax(temp)
                psi[n,t] = max_ind
                delta[n,t] = self.B[n,obs[t]-1] * temp[max_ind]

        max_ind = argmax(delta[:,T-1])
        q[T-1] = max_ind
        prob = delta[:,T-1][max_ind]

        for t in reversed(xrange(1,T-1)):
            q[t] = psi[q[t+1],t+1]    
            
        return prob, q, delta    
        
    def viterbi_log(self, obs):
        
        T = len(obs)
        N = self.N
        psi = np.zeros([N,T])
        delta = np.zeros([N,T])
        pi = np.zeros(self.pi.shape)
        A = np.zeros(self.A.shape)
        biot = np.zeros([N,T])

        pi = np.log(self.pi)        
        A = np.log(self.A)
        biot = np.log(self.B[:,obs[:]-1])

        delta[:,0] = pi[:] + biot[:,0]

        for t in xrange(1,T):
            for n in xrange(0,N):
                temp = delta[:,t-1] + self.A[:,n]    
                max_ind = argmax(temp)
                psi[n,t] = max_ind
                delta[n,t] = temp[max_ind] + biot[n,t]   

        max_ind = argmax(delta[:,T-1])
        q[T-1] = max_ind            
        logprob = delta[max_ind,T-1]      
                
        for t in reversed(xrange(1,T-1)):
            q[t] = psi[q[t+1],t+1]    

        return logprob, q, delta

    def baum_welch(self, obs):
        T = len(obs)
        M = self.M
        N = self.N        
        alpha = np.zeros([N,T])
        beta = np.zeros([N,T])
        scale = np.zeros(T)
        gamma = np.zeros([N,T])
        xi = np.zeros([N,N,T-1])
    
        # caculate initial parameters
        logprobprev, alpha, scale = self.forward_with_scale(obs)
        beta = self.backward_with_scale(obs, scale)            
        gamma = self.compute_gamma(alpha, beta)    
        xi = self.compute_xi(obs, alpha, beta)    
        logprobinit = logprobprev        
        
        # start interative 
        while True:
            # E-step
            self.pi = 0.001 + 0.999*gamma[:,0]
            for i in xrange(N):
                denominator = np.sum(gamma[i,0:T-1])
                for j in xrange(N): 
                    numerator = np.sum(xi[i,j,0:T-1])
                    self.A[i,j] = numerator / denominator
                                   
            self.A = 0.001 + 0.999*self.A
            for j in xrange(0,N):
                denominator = np.sum(gamma[j,:])
                for k in xrange(0,M):
                    numerator = 0.0
                    for t in xrange(0,T):
                        if obs[t]-1 == k:
                            numerator += gamma[j,t]
                    self.B[j,k] = numerator / denominator
            self.B = 0.001 + 0.999*self.B

            # M-step
            logprobcur, alpha, scale = self.forward_with_scale(obs)
            beta = self.backward_with_scale(obs, scale)            
            gamma = self.compute_gamma(alpha, beta)    
            xi = self.compute_xi(obs, alpha, beta)    

            delta = logprobcur - logprobprev
            logprobprev = logprobcur
            # print "delta is ", delta
            if delta <= DELTA:
                break     
                
        logprobfinal = logprobcur
        return logprobinit, logprobfinal                
            
    def compute_gamma(self, alpha, beta):
        gamma = np.zeros(alpha.shape)
        gamma = alpha[:,:] * beta[:,:]
        gamma = gamma / np.sum(gamma,0)
        return gamma
            
    def compute_xi(self, obs, alpha, beta):
        T = len(obs)
        N = self.N
        xi = np.zeros((N, N, T-1))
            
        for t in xrange(0,T-1):        
            for i in xrange(0,N):
                for j in xrange(0,N):
                    xi[i,j,t] = alpha[i,t] * self.A[i,j] * \
                                self.B[j,obs[t+1]-1] * beta[j,t+1]
            xi[:,:,t] /= np.sum(np.sum(xi[:,:,t],1),0)    
        return xi

def read_hmm(hmmfile):
    fhmm = open(hmmfile,'r') 

    M = int(fhmm.readline().split(' ')[1])
    N = int(fhmm.readline().split(' ')[1]) 
    
    A = np.array([])
    fhmm.readline()
    for i in xrange(N):
        line = fhmm.readline()
        if i == 0:
            A = np.array(map(float,line.split(',')))
        else:
            A = np.vstack((A,map(float,line.split(','))))
        
    B = np.array([])
    fhmm.readline()
    for i in xrange(N):
        line = fhmm.readline()
        if i == 0:
            B = np.array(map(float,line.split(',')))
        else:
            B = np.vstack((B,map(float,line.split(','))))
    
    fhmm.readline()
    line = fhmm.readline()
    pi = np.array(map(float,line.split(',')))
    
    fhmm.close()
    return M, N, pi, A, B 
    
def read_sequence(seqfile):
    fseq = open(seqfile,'r') 
    
    T = int(fseq.readline().split(' ')[1])
    line = fseq.readline()
    obs = np.array(map(int,line.split(',')))
    
    fseq.close()
    return T, obs
复制代码

 


本文转自ZH奶酪博客园博客,原文链接:http://www.cnblogs.com/CheeseZH/p/4229910.html,如需转载请自行联系原作者

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