I tried to implement speaker verification using Hidden Markov Models. I followed this tutorial: http://compbio.ucdenver.edu/hunter/cpbs7711/2010_09_09_Rabiner1989_HMMTutorial_Erratum_Leach.pdf

Apparently, I have been getting wrong results with the transition matrix values. I think, or am I wrong. The sum of the probabilities for each row in the transition matrix results to less than 1. Is that supposed to happen for multiple observations? Also, are the observations supposed to have the same length? I used MFCC and quantized them using Kmeans. Should I make sure they are of the same length? Any help would be appreciated. Trying to search for other sources but kinda lost.

```
# Function for getting the xi and epsilon values
def ep_xi(self, states, obs, alphabet, init_pi, transition_matrix, emission_matrix, a, b):
ip = deepcopy(init_pi)
tm = deepcopy(transition_matrix)
em = deepcopy(emission_matrix)
coef = deepcopy(a["coef"])
alpha = deepcopy(a["alpha"])
beta = deepcopy(b)
T = len(obs)
epsilon = {}
xi = {}
epsilon[0] = None
for t in range(1, T):
epsilon[t] = {}
for i in states:
epsilon[t][i] = []
for j in states:
below = 0
epsilon_t = alpha[t-1][i] * tm[i][j] * em[j][obs[t]] * beta[t][j]
for k in states:
below += (alpha[t][k] * beta[t][k])
if below > 0: epsilon[t][i].append(epsilon_t/below)
else: epsilon[t][i].append(0)
for t in range(0, T):
xi[t] = []
for i in states:
xi_t = alpha[t][i] * beta[t][i]
below = 0
for j in states:
below += (alpha[t][j] * beta[t][j])
if below == 0: xi_t = 0
else: xi_t /= below
xi[t].append(xi_t)
# Function for reestimating the matrices values
def m_reestimate(self, obs, alphabet, xi_list, epsilon_list, prob_list):
T = len(obs)
xi_list = deepcopy(xi_list)
epsilon_list = deepcopy(epsilon_list)
pi = {}
trans = {}
emis = {}
# Initial matrix
for i in range(0, len(states)): pi[states[i]] = xi_list[0][0][i]
# Transition matrix
for i in range(0, len(states)):
trans[states[i]] = {}
for j in range(0, len(states)):
above = 0
below = 0
for epsilon in epsilon_list:
index = epsilon_list.index(epsilon)
for t in range(1, len(obs[index])):
above += epsilon[t][states[i]][j]
for xi in xi_list:
index = xi_list.index(xi)
for t in range(0, len(obs[index])):
below += xi[t][i]
if below == 0: trans[states[i]][states[j]] = 0
else: trans[states[i]][states[j]] = above / below
# Emission matrix
for j in range(0, len(states)):
emis[states[j]] = []
for char in alphabet:
above = 0
below = 0
for xi in xi_list:
index = xi_list.index(xi)
for t in range(0, len(xi)):
if obs[index][t] == char: above += xi[t][j]
below += xi[t][j]
if below == 0: emis_t = 0
else: emis_t = float(above) / below
emis[states[j]].append(emis_t)
return {"init": init, "trans": trans, "emis": emis}
```