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steminc
steminc / scikit-learn python
Repository URL to install this package:
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Version:
0.15.2 ▾
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scikit-learn
/
hmm.py
|
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# Hidden Markov Models
#
# Author: Ron Weiss <ronweiss@gmail.com>
# and Shiqiao Du <lucidfrontier.45@gmail.com>
# API changes: Jaques Grobler <jaquesgrobler@gmail.com>
"""
The :mod:`sklearn.hmm` module implements hidden Markov models.
**Warning:** :mod:`sklearn.hmm` is orphaned, undocumented and has known
numerical stability issues. This module will be removed in version 0.17.
It has been moved to a separate repository:
https://github.com/hmmlearn/hmmlearn
"""
import string
import numpy as np
from .utils import check_random_state, deprecated
from .utils.extmath import logsumexp
from .base import BaseEstimator
from .mixture import (
GMM, log_multivariate_normal_density, sample_gaussian,
distribute_covar_matrix_to_match_covariance_type, _validate_covars)
from . import cluster
from . import _hmmc
__all__ = ['GMMHMM',
'GaussianHMM',
'MultinomialHMM',
'decoder_algorithms',
'normalize']
ZEROLOGPROB = -1e200
EPS = np.finfo(float).eps
NEGINF = -np.inf
decoder_algorithms = ("viterbi", "map")
@deprecated("WARNING: The HMM module and its functions will be removed in 0.17 "
"as it no longer falls within the project's scope and API. "
"It has been moved to a separate repository: "
"https://github.com/hmmlearn/hmmlearn")
def normalize(A, axis=None):
""" Normalize the input array so that it sums to 1.
WARNING: The HMM module and its functions will be removed in 0.17
as it no longer falls within the project's scope and API.
Parameters
----------
A: array, shape (n_samples, n_features)
Non-normalized input data
axis: int
dimension along which normalization is performed
Returns
-------
normalized_A: array, shape (n_samples, n_features)
A with values normalized (summing to 1) along the prescribed axis
WARNING: Modifies inplace the array
"""
A += EPS
Asum = A.sum(axis)
if axis and A.ndim > 1:
# Make sure we don't divide by zero.
Asum[Asum == 0] = 1
shape = list(A.shape)
shape[axis] = 1
Asum.shape = shape
return A / Asum
@deprecated("WARNING: The HMM module and its function will be removed in 0.17"
"as it no longer falls within the project's scope and API. "
"It has been moved to a separate repository: "
"https://github.com/hmmlearn/hmmlearn")
class _BaseHMM(BaseEstimator):
"""Hidden Markov Model base class.
Representation of a hidden Markov model probability distribution.
This class allows for easy evaluation of, sampling from, and
maximum-likelihood estimation of the parameters of a HMM.
See the instance documentation for details specific to a
particular object.
.. warning::
The HMM module and its functions will be removed in 0.17
as it no longer falls within the project's scope and API.
Attributes
----------
n_components : int
Number of states in the model.
transmat : array, shape (`n_components`, `n_components`)
Matrix of transition probabilities between states.
startprob : array, shape ('n_components`,)
Initial state occupation distribution.
transmat_prior : array, shape (`n_components`, `n_components`)
Matrix of prior transition probabilities between states.
startprob_prior : array, shape ('n_components`,)
Initial state occupation prior distribution.
algorithm : string, one of the decoder_algorithms
decoder algorithm
random_state: RandomState or an int seed (0 by default)
A random number generator instance
n_iter : int, optional
Number of iterations to perform.
thresh : float, optional
Convergence threshold.
params : string, optional
Controls which parameters are updated in the training
process. Can contain any combination of 's' for startprob,
't' for transmat, and other characters for subclass-specific
emmission parameters. Defaults to all parameters.
init_params : string, optional
Controls which parameters are initialized prior to
training. Can contain any combination of 's' for
startprob, 't' for transmat, and other characters for
subclass-specific emmission parameters. Defaults to all
parameters.
See Also
--------
GMM : Gaussian mixture model
"""
# This class implements the public interface to all HMMs that
# derive from it, including all of the machinery for the
# forward-backward and Viterbi algorithms. Subclasses need only
# implement _generate_sample_from_state(), _compute_log_likelihood(),
# _init(), _initialize_sufficient_statistics(),
# _accumulate_sufficient_statistics(), and _do_mstep(), all of
# which depend on the specific emission distribution.
#
# Subclasses will probably also want to implement properties for
# the emission distribution parameters to expose them publicly.
def __init__(self, n_components=1, startprob=None, transmat=None,
startprob_prior=None, transmat_prior=None,
algorithm="viterbi", random_state=None,
n_iter=10, thresh=1e-2, params=string.ascii_letters,
init_params=string.ascii_letters):
self.n_components = n_components
self.n_iter = n_iter
self.thresh = thresh
self.params = params
self.init_params = init_params
self.startprob_ = startprob
self.startprob_prior = startprob_prior
self.transmat_ = transmat
self.transmat_prior = transmat_prior
self._algorithm = algorithm
self.random_state = random_state
def eval(self, X):
return self.score_samples(X)
def score_samples(self, obs):
"""Compute the log probability under the model and compute posteriors.
Parameters
----------
obs : array_like, shape (n, n_features)
Sequence of n_features-dimensional data points. Each row
corresponds to a single point in the sequence.
Returns
-------
logprob : float
Log likelihood of the sequence ``obs``.
posteriors : array_like, shape (n, n_components)
Posterior probabilities of each state for each
observation
See Also
--------
score : Compute the log probability under the model
decode : Find most likely state sequence corresponding to a `obs`
"""
obs = np.asarray(obs)
framelogprob = self._compute_log_likelihood(obs)
logprob, fwdlattice = self._do_forward_pass(framelogprob)
bwdlattice = self._do_backward_pass(framelogprob)
gamma = fwdlattice + bwdlattice
# gamma is guaranteed to be correctly normalized by logprob at
# all frames, unless we do approximate inference using pruning.
# So, we will normalize each frame explicitly in case we
# pruned too aggressively.
posteriors = np.exp(gamma.T - logsumexp(gamma, axis=1)).T
posteriors += np.finfo(np.float32).eps
posteriors /= np.sum(posteriors, axis=1).reshape((-1, 1))
return logprob, posteriors
def score(self, obs):
"""Compute the log probability under the model.
Parameters
----------
obs : array_like, shape (n, n_features)
Sequence of n_features-dimensional data points. Each row
corresponds to a single data point.
Returns
-------
logprob : float
Log likelihood of the ``obs``.
See Also
--------
score_samples : Compute the log probability under the model and
posteriors
decode : Find most likely state sequence corresponding to a `obs`
"""
obs = np.asarray(obs)
framelogprob = self._compute_log_likelihood(obs)
logprob, _ = self._do_forward_pass(framelogprob)
return logprob
def _decode_viterbi(self, obs):
"""Find most likely state sequence corresponding to ``obs``.
Uses the Viterbi algorithm.
Parameters
----------
obs : array_like, shape (n, n_features)
Sequence of n_features-dimensional data points. Each row
corresponds to a single point in the sequence.
Returns
-------
viterbi_logprob : float
Log probability of the maximum likelihood path through the HMM.
state_sequence : array_like, shape (n,)
Index of the most likely states for each observation.
See Also
--------
score_samples : Compute the log probability under the model and
posteriors.
score : Compute the log probability under the model
"""
obs = np.asarray(obs)
framelogprob = self._compute_log_likelihood(obs)
viterbi_logprob, state_sequence = self._do_viterbi_pass(framelogprob)
return viterbi_logprob, state_sequence
def _decode_map(self, obs):
"""Find most likely state sequence corresponding to `obs`.
Uses the maximum a posteriori estimation.
Parameters
----------
obs : array_like, shape (n, n_features)
Sequence of n_features-dimensional data points. Each row
corresponds to a single point in the sequence.
Returns
-------
map_logprob : float
Log probability of the maximum likelihood path through the HMM
state_sequence : array_like, shape (n,)
Index of the most likely states for each observation
See Also
--------
score_samples : Compute the log probability under the model and
posteriors.
score : Compute the log probability under the model.
"""
_, posteriors = self.score_samples(obs)
state_sequence = np.argmax(posteriors, axis=1)
map_logprob = np.max(posteriors, axis=1).sum()
return map_logprob, state_sequence
def decode(self, obs, algorithm="viterbi"):
"""Find most likely state sequence corresponding to ``obs``.
Uses the selected algorithm for decoding.
Parameters
----------
obs : array_like, shape (n, n_features)
Sequence of n_features-dimensional data points. Each row
corresponds to a single point in the sequence.
algorithm : string, one of the `decoder_algorithms`
decoder algorithm to be used
Returns
-------
logprob : float
Log probability of the maximum likelihood path through the HMM
state_sequence : array_like, shape (n,)
Index of the most likely states for each observation
See Also
--------
score_samples : Compute the log probability under the model and
posteriors.
score : Compute the log probability under the model.
"""
if self._algorithm in decoder_algorithms:
algorithm = self._algorithm
elif algorithm in decoder_algorithms:
algorithm = algorithm
decoder = {"viterbi": self._decode_viterbi,
"map": self._decode_map}
logprob, state_sequence = decoder[algorithm](obs)
return logprob, state_sequence
def predict(self, obs, algorithm="viterbi"):
"""Find most likely state sequence corresponding to `obs`.
Parameters
----------
obs : array_like, shape (n, n_features)
Sequence of n_features-dimensional data points. Each row
corresponds to a single point in the sequence.
Returns
-------
state_sequence : array_like, shape (n,)
Index of the most likely states for each observation
"""
_, state_sequence = self.decode(obs, algorithm)
return state_sequence
def predict_proba(self, obs):
"""Compute the posterior probability for each state in the model
Parameters
----------
obs : array_like, shape (n, n_features)
Sequence of n_features-dimensional data points. Each row
corresponds to a single point in the sequence.
Returns
-------
T : array-like, shape (n, n_components)
Returns the probability of the sample for each state in the model.
"""
_, posteriors = self.score_samples(obs)
return posteriors
def sample(self, n=1, random_state=None):
"""Generate random samples from the model.
Parameters
----------
n : int
Number of samples to generate.
random_state: RandomState or an int seed (0 by default)
A random number generator instance. If None is given, the
object's random_state is used
Returns
-------
(obs, hidden_states)
obs : array_like, length `n` List of samples
hidden_states : array_like, length `n` List of hidden states
"""
if random_state is None:
random_state = self.random_state
random_state = check_random_state(random_state)
startprob_pdf = self.startprob_
startprob_cdf = np.cumsum(startprob_pdf)
transmat_pdf = self.transmat_
transmat_cdf = np.cumsum(transmat_pdf, 1)
# Initial state.
rand = random_state.rand()
currstate = (startprob_cdf > rand).argmax()
hidden_states = [currstate]
obs = [self._generate_sample_from_state(
currstate, random_state=random_state)]
for _ in range(n - 1):
rand = random_state.rand()
currstate = (transmat_cdf[currstate] > rand).argmax()
hidden_states.append(currstate)
obs.append(self._generate_sample_from_state(
currstate, random_state=random_state))
return np.array(obs), np.array(hidden_states, dtype=int)
def fit(self, obs):
"""Estimate model parameters.
An initialization step is performed before entering the EM
algorithm. If you want to avoid this step, pass proper
``init_params`` keyword argument to estimator's constructor.
Parameters
----------
obs : list
List of array-like observation sequences, each of which
has shape (n_i, n_features), where n_i is the length of
the i_th observation.
Notes
-----
In general, `logprob` should be non-decreasing unless
aggressive pruning is used. Decreasing `logprob` is generally
a sign of overfitting (e.g. a covariance parameter getting too
small). You can fix this by getting more training data,
or strengthening the appropriate subclass-specific regularization
parameter.
"""
if self.algorithm not in decoder_algorithms:
self._algorithm = "viterbi"
self._init(obs, self.init_params)
logprob = []
for i in range(self.n_iter):
# Expectation step
stats = self._initialize_sufficient_statistics()
curr_logprob = 0
for seq in obs:
framelogprob = self._compute_log_likelihood(seq)
lpr, fwdlattice = self._do_forward_pass(framelogprob)
bwdlattice = self._do_backward_pass(framelogprob)
gamma = fwdlattice + bwdlattice
posteriors = np.exp(gamma.T - logsumexp(gamma, axis=1)).T
curr_logprob += lpr
self._accumulate_sufficient_statistics(
stats, seq, framelogprob, posteriors, fwdlattice,
bwdlattice, self.params)
logprob.append(curr_logprob)
# Check for convergence.
if i > 0 and abs(logprob[-1] - logprob[-2]) < self.thresh:
break
# Maximization step
self._do_mstep(stats, self.params)
return self
def _get_algorithm(self):
"decoder algorithm"
return self._algorithm
def _set_algorithm(self, algorithm):
if algorithm not in decoder_algorithms:
raise ValueError("algorithm must be one of the decoder_algorithms")
self._algorithm = algorithm
algorithm = property(_get_algorithm, _set_algorithm)
def _get_startprob(self):
"""Mixing startprob for each state."""
return np.exp(self._log_startprob)
def _set_startprob(self, startprob):
if startprob is None:
startprob = np.tile(1.0 / self.n_components, self.n_components)
else:
startprob = np.asarray(startprob, dtype=np.float)
# check if there exists a component whose value is exactly zero
# if so, add a small number and re-normalize
if not np.alltrue(startprob):
normalize(startprob)
if len(startprob) != self.n_components:
raise ValueError('startprob must have length n_components')
if not np.allclose(np.sum(startprob), 1.0):
raise ValueError('startprob must sum to 1.0')
self._log_startprob = np.log(np.asarray(startprob).copy())
startprob_ = property(_get_startprob, _set_startprob)
def _get_transmat(self):
"""Matrix of transition probabilities."""
return np.exp(self._log_transmat)
def _set_transmat(self, transmat):
if transmat is None:
transmat = np.tile(1.0 / self.n_components,
(self.n_components, self.n_components))
# check if there exists a component whose value is exactly zero
# if so, add a small number and re-normalize
if not np.alltrue(transmat):
normalize(transmat, axis=1)
if (np.asarray(transmat).shape
!= (self.n_components, self.n_components)):
raise ValueError('transmat must have shape '
'(n_components, n_components)')
if not np.all(np.allclose(np.sum(transmat, axis=1), 1.0)):
raise ValueError('Rows of transmat must sum to 1.0')
self._log_transmat = np.log(np.asarray(transmat).copy())
underflow_idx = np.isnan(self._log_transmat)
self._log_transmat[underflow_idx] = NEGINF
transmat_ = property(_get_transmat, _set_transmat)
def _do_viterbi_pass(self, framelogprob):
n_observations, n_components = framelogprob.shape
state_sequence, logprob = _hmmc._viterbi(
n_observations, n_components, self._log_startprob,
self._log_transmat, framelogprob)
return logprob, state_sequence
def _do_forward_pass(self, framelogprob):
n_observations, n_components = framelogprob.shape
fwdlattice = np.zeros((n_observations, n_components))
_hmmc._forward(n_observations, n_components, self._log_startprob,
self._log_transmat, framelogprob, fwdlattice)
fwdlattice[fwdlattice <= ZEROLOGPROB] = NEGINF
return logsumexp(fwdlattice[-1]), fwdlattice
def _do_backward_pass(self, framelogprob):
n_observations, n_components = framelogprob.shape
bwdlattice = np.zeros((n_observations, n_components))
_hmmc._backward(n_observations, n_components, self._log_startprob,
self._log_transmat, framelogprob, bwdlattice)
bwdlattice[bwdlattice <= ZEROLOGPROB] = NEGINF
return bwdlattice
def _compute_log_likelihood(self, obs):
pass
def _generate_sample_from_state(self, state, random_state=None):
pass
def _init(self, obs, params):
if 's' in params:
self.startprob_.fill(1.0 / self.n_components)
if 't' in params:
self.transmat_.fill(1.0 / self.n_components)
# Methods used by self.fit()
def _initialize_sufficient_statistics(self):
stats = {'nobs': 0,
'start': np.zeros(self.n_components),
'trans': np.zeros((self.n_components, self.n_components))}
return stats
def _accumulate_sufficient_statistics(self, stats, seq, framelogprob,
posteriors, fwdlattice, bwdlattice,
params):
stats['nobs'] += 1
if 's' in params:
stats['start'] += posteriors[0]
if 't' in params:
n_observations, n_components = framelogprob.shape
# when the sample is of length 1, it contains no transitions
# so there is no reason to update our trans. matrix estimate
if n_observations > 1:
lneta = np.zeros((n_observations - 1, n_components, n_components))
lnP = logsumexp(fwdlattice[-1])
_hmmc._compute_lneta(n_observations, n_components, fwdlattice,
self._log_transmat, bwdlattice, framelogprob,
lnP, lneta)
stats['trans'] += np.exp(np.minimum(logsumexp(lneta, 0), 700))
def _do_mstep(self, stats, params):
# Based on Huang, Acero, Hon, "Spoken Language Processing",
# p. 443 - 445
if self.startprob_prior is None:
self.startprob_prior = 1.0
if self.transmat_prior is None:
self.transmat_prior = 1.0
if 's' in params:
self.startprob_ = normalize(
np.maximum(self.startprob_prior - 1.0 + stats['start'], 1e-20))
if 't' in params:
transmat_ = normalize(
np.maximum(self.transmat_prior - 1.0 + stats['trans'], 1e-20),
axis=1)
self.transmat_ = transmat_
class GaussianHMM(_BaseHMM):
"""Hidden Markov Model with Gaussian emissions
Representation of a hidden Markov model probability distribution.
This class allows for easy evaluation of, sampling from, and
maximum-likelihood estimation of the parameters of a HMM.
.. warning::
The HMM module and its functions will be removed in 0.17
as it no longer falls within the project's scope and API.
Parameters
----------
n_components : int
Number of states.
``_covariance_type`` : string
String describing the type of covariance parameters to
use. Must be one of 'spherical', 'tied', 'diag', 'full'.
Defaults to 'diag'.
Attributes
----------
``_covariance_type`` : string
String describing the type of covariance parameters used by
the model. Must be one of 'spherical', 'tied', 'diag', 'full'.
n_features : int
Dimensionality of the Gaussian emissions.
n_components : int
Number of states in the model.
transmat : array, shape (`n_components`, `n_components`)
Matrix of transition probabilities between states.
startprob : array, shape ('n_components`,)
Initial state occupation distribution.
means : array, shape (`n_components`, `n_features`)
Mean parameters for each state.
covars : array
Covariance parameters for each state. The shape depends on
``_covariance_type``::
(`n_components`,) if 'spherical',
(`n_features`, `n_features`) if 'tied',
(`n_components`, `n_features`) if 'diag',
(`n_components`, `n_features`, `n_features`) if 'full'
random_state: RandomState or an int seed (0 by default)
A random number generator instance
n_iter : int, optional
Number of iterations to perform.
thresh : float, optional
Convergence threshold.
params : string, optional
Controls which parameters are updated in the training
process. Can contain any combination of 's' for startprob,
't' for transmat, 'm' for means, and 'c' for covars.
Defaults to all parameters.
init_params : string, optional
Controls which parameters are initialized prior to
training. Can contain any combination of 's' for
startprob, 't' for transmat, 'm' for means, and 'c' for
covars. Defaults to all parameters.
Examples
--------
>>> from sklearn.hmm import GaussianHMM
>>> GaussianHMM(n_components=2)
... #doctest: +ELLIPSIS +NORMALIZE_WHITESPACE
GaussianHMM(algorithm='viterbi',...
See Also
--------
GMM : Gaussian mixture model
"""
def __init__(self, n_components=1, covariance_type='diag', startprob=None,
transmat=None, startprob_prior=None, transmat_prior=None,
algorithm="viterbi", means_prior=None, means_weight=0,
covars_prior=1e-2, covars_weight=1,
random_state=None, n_iter=10, thresh=1e-2,
params=string.ascii_letters,
init_params=string.ascii_letters):
_BaseHMM.__init__(self, n_components, startprob, transmat,
startprob_prior=startprob_prior,
transmat_prior=transmat_prior, algorithm=algorithm,
random_state=random_state, n_iter=n_iter,
thresh=thresh, params=params,
init_params=init_params)
self._covariance_type = covariance_type
if not covariance_type in ['spherical', 'tied', 'diag', 'full']:
raise ValueError('bad covariance_type')
self.means_prior = means_prior
self.means_weight = means_weight
self.covars_prior = covars_prior
self.covars_weight = covars_weight
@property
def covariance_type(self):
"""Covariance type of the model.
Must be one of 'spherical', 'tied', 'diag', 'full'.
"""
return self._covariance_type
def _get_means(self):
"""Mean parameters for each state."""
return self._means_
def _set_means(self, means):
means = np.asarray(means)
if (hasattr(self, 'n_features')
and means.shape != (self.n_components, self.n_features)):
raise ValueError('means must have shape '
'(n_components, n_features)')
self._means_ = means.copy()
self.n_features = self._means_.shape[1]
means_ = property(_get_means, _set_means)
def _get_covars(self):
"""Return covars as a full matrix."""
if self._covariance_type == 'full':
return self._covars_
elif self._covariance_type == 'diag':
return [np.diag(cov) for cov in self._covars_]
elif self._covariance_type == 'tied':
return [self._covars_] * self.n_components
elif self._covariance_type == 'spherical':
return [np.eye(self.n_features) * f for f in self._covars_]
def _set_covars(self, covars):
covars = np.asarray(covars)
_validate_covars(covars, self._covariance_type, self.n_components)
self._covars_ = covars.copy()
covars_ = property(_get_covars, _set_covars)
def _compute_log_likelihood(self, obs):
return log_multivariate_normal_density(
obs, self._means_, self._covars_, self._covariance_type)
def _generate_sample_from_state(self, state, random_state=None):
if self._covariance_type == 'tied':
cv = self._covars_
else:
cv = self._covars_[state]
return sample_gaussian(self._means_[state], cv, self._covariance_type,
random_state=random_state)
def _init(self, obs, params='stmc'):
super(GaussianHMM, self)._init(obs, params=params)
if (hasattr(self, 'n_features')
and self.n_features != obs[0].shape[1]):
raise ValueError('Unexpected number of dimensions, got %s but '
'expected %s' % (obs[0].shape[1],
self.n_features))
self.n_features = obs[0].shape[1]
if 'm' in params:
self._means_ = cluster.KMeans(
n_clusters=self.n_components).fit(obs[0]).cluster_centers_
if 'c' in params:
cv = np.cov(obs[0].T)
if not cv.shape:
cv.shape = (1, 1)
self._covars_ = distribute_covar_matrix_to_match_covariance_type(
cv, self._covariance_type, self.n_components)
self._covars_[self._covars_ == 0] = 1e-5
def _initialize_sufficient_statistics(self):
stats = super(GaussianHMM, self)._initialize_sufficient_statistics()
stats['post'] = np.zeros(self.n_components)
stats['obs'] = np.zeros((self.n_components, self.n_features))
stats['obs**2'] = np.zeros((self.n_components, self.n_features))
stats['obs*obs.T'] = np.zeros((self.n_components, self.n_features,
self.n_features))
return stats
def _accumulate_sufficient_statistics(self, stats, obs, framelogprob,
posteriors, fwdlattice, bwdlattice,
params):
super(GaussianHMM, self)._accumulate_sufficient_statistics(
stats, obs, framelogprob, posteriors, fwdlattice, bwdlattice,
params)
if 'm' in params or 'c' in params:
stats['post'] += posteriors.sum(axis=0)
stats['obs'] += np.dot(posteriors.T, obs)
if 'c' in params:
if self._covariance_type in ('spherical', 'diag'):
stats['obs**2'] += np.dot(posteriors.T, obs ** 2)
elif self._covariance_type in ('tied', 'full'):
for t, o in enumerate(obs):
obsobsT = np.outer(o, o)
for c in range(self.n_components):
stats['obs*obs.T'][c] += posteriors[t, c] * obsobsT
def _do_mstep(self, stats, params):
super(GaussianHMM, self)._do_mstep(stats, params)
# Based on Huang, Acero, Hon, "Spoken Language Processing",
# p. 443 - 445
denom = stats['post'][:, np.newaxis]
if 'm' in params:
prior = self.means_prior
weight = self.means_weight
if prior is None:
weight = 0
prior = 0
self._means_ = (weight * prior + stats['obs']) / (weight + denom)
if 'c' in params:
covars_prior = self.covars_prior
covars_weight = self.covars_weight
if covars_prior is None:
covars_weight = 0
covars_prior = 0
means_prior = self.means_prior
means_weight = self.means_weight
if means_prior is None:
means_weight = 0
means_prior = 0
meandiff = self._means_ - means_prior
if self._covariance_type in ('spherical', 'diag'):
cv_num = (means_weight * (meandiff) ** 2
+ stats['obs**2']
- 2 * self._means_ * stats['obs']
+ self._means_ ** 2 * denom)
cv_den = max(covars_weight - 1, 0) + denom
self._covars_ = (covars_prior + cv_num) / np.maximum(cv_den, 1e-5)
if self._covariance_type == 'spherical':
self._covars_ = np.tile(
self._covars_.mean(1)[:, np.newaxis],
(1, self._covars_.shape[1]))
elif self._covariance_type in ('tied', 'full'):
cvnum = np.empty((self.n_components, self.n_features,
self.n_features))
for c in range(self.n_components):
obsmean = np.outer(stats['obs'][c], self._means_[c])
cvnum[c] = (means_weight * np.outer(meandiff[c],
meandiff[c])
+ stats['obs*obs.T'][c]
- obsmean - obsmean.T
+ np.outer(self._means_[c], self._means_[c])
* stats['post'][c])
cvweight = max(covars_weight - self.n_features, 0)
if self._covariance_type == 'tied':
self._covars_ = ((covars_prior + cvnum.sum(axis=0)) /
(cvweight + stats['post'].sum()))
elif self._covariance_type == 'full':
self._covars_ = ((covars_prior + cvnum) /
(cvweight + stats['post'][:, None, None]))
def fit(self, obs):
"""Estimate model parameters.
An initialization step is performed before entering the EM
algorithm. If you want to avoid this step, pass proper
``init_params`` keyword argument to estimator's constructor.
Parameters
----------
obs : list
List of array-like observation sequences, each of which
has shape (n_i, n_features), where n_i is the length of
the i_th observation.
Notes
-----
In general, `logprob` should be non-decreasing unless
aggressive pruning is used. Decreasing `logprob` is generally
a sign of overfitting (e.g. the covariance parameter on one or
more components becomminging too small). You can fix this by getting
more training data, or increasing covars_prior.
"""
return super(GaussianHMM, self).fit(obs)
class MultinomialHMM(_BaseHMM):
"""Hidden Markov Model with multinomial (discrete) emissions
.. warning::
The HMM module and its functions will be removed in 0.17
as it no longer falls within the project's scope and API.
Attributes
----------
n_components : int
Number of states in the model.
n_symbols : int
Number of possible symbols emitted by the model (in the observations).
transmat : array, shape (`n_components`, `n_components`)
Matrix of transition probabilities between states.
startprob : array, shape ('n_components`,)
Initial state occupation distribution.
emissionprob : array, shape ('n_components`, 'n_symbols`)
Probability of emitting a given symbol when in each state.
random_state: RandomState or an int seed (0 by default)
A random number generator instance
n_iter : int, optional
Number of iterations to perform.
thresh : float, optional
Convergence threshold.
params : string, optional
Controls which parameters are updated in the training
process. Can contain any combination of 's' for startprob,
't' for transmat, 'e' for emmissionprob.
Defaults to all parameters.
init_params : string, optional
Controls which parameters are initialized prior to
training. Can contain any combination of 's' for
startprob, 't' for transmat, 'e' for emmissionprob.
Defaults to all parameters.
Examples
--------
>>> from sklearn.hmm import MultinomialHMM
>>> MultinomialHMM(n_components=2)
... #doctest: +ELLIPSIS +NORMALIZE_WHITESPACE
MultinomialHMM(algorithm='viterbi',...
See Also
--------
GaussianHMM : HMM with Gaussian emissions
"""
def __init__(self, n_components=1, startprob=None, transmat=None,
startprob_prior=None, transmat_prior=None,
algorithm="viterbi", random_state=None,
n_iter=10, thresh=1e-2, params=string.ascii_letters,
init_params=string.ascii_letters):
"""Create a hidden Markov model with multinomial emissions.
Parameters
----------
n_components : int
Number of states.
"""
_BaseHMM.__init__(self, n_components, startprob, transmat,
startprob_prior=startprob_prior,
transmat_prior=transmat_prior,
algorithm=algorithm,
random_state=random_state,
n_iter=n_iter,
thresh=thresh,
params=params,
init_params=init_params)
def _get_emissionprob(self):
"""Emission probability distribution for each state."""
return np.exp(self._log_emissionprob)
def _set_emissionprob(self, emissionprob):
emissionprob = np.asarray(emissionprob)
if hasattr(self, 'n_symbols') and \
emissionprob.shape != (self.n_components, self.n_symbols):
raise ValueError('emissionprob must have shape '
'(n_components, n_symbols)')
# check if there exists a component whose value is exactly zero
# if so, add a small number and re-normalize
if not np.alltrue(emissionprob):
normalize(emissionprob)
self._log_emissionprob = np.log(emissionprob)
underflow_idx = np.isnan(self._log_emissionprob)
self._log_emissionprob[underflow_idx] = NEGINF
self.n_symbols = self._log_emissionprob.shape[1]
emissionprob_ = property(_get_emissionprob, _set_emissionprob)
def _compute_log_likelihood(self, obs):
return self._log_emissionprob[:, obs].T
def _generate_sample_from_state(self, state, random_state=None):
cdf = np.cumsum(self.emissionprob_[state, :])
random_state = check_random_state(random_state)
rand = random_state.rand()
symbol = (cdf > rand).argmax()
return symbol
def _init(self, obs, params='ste'):
super(MultinomialHMM, self)._init(obs, params=params)
self.random_state = check_random_state(self.random_state)
if 'e' in params:
if not hasattr(self, 'n_symbols'):
symbols = set()
for o in obs:
symbols = symbols.union(set(o))
self.n_symbols = len(symbols)
emissionprob = normalize(self.random_state.rand(self.n_components,
self.n_symbols), 1)
self.emissionprob_ = emissionprob
def _initialize_sufficient_statistics(self):
stats = super(MultinomialHMM, self)._initialize_sufficient_statistics()
stats['obs'] = np.zeros((self.n_components, self.n_symbols))
return stats
def _accumulate_sufficient_statistics(self, stats, obs, framelogprob,
posteriors, fwdlattice, bwdlattice,
params):
super(MultinomialHMM, self)._accumulate_sufficient_statistics(
stats, obs, framelogprob, posteriors, fwdlattice, bwdlattice,
params)
if 'e' in params:
for t, symbol in enumerate(obs):
stats['obs'][:, symbol] += posteriors[t]
def _do_mstep(self, stats, params):
super(MultinomialHMM, self)._do_mstep(stats, params)
if 'e' in params:
self.emissionprob_ = (stats['obs']
/ stats['obs'].sum(1)[:, np.newaxis])
def _check_input_symbols(self, obs):
"""check if input can be used for Multinomial.fit input must be both
positive integer array and every element must be continuous.
e.g. x = [0, 0, 2, 1, 3, 1, 1] is OK and y = [0, 0, 3, 5, 10] not
"""
symbols = np.asarray(obs).flatten()
if symbols.dtype.kind != 'i':
# input symbols must be integer
return False
if len(symbols) == 1:
# input too short
return False
if np.any(symbols < 0):
# input contains negative intiger
return False
symbols.sort()
if np.any(np.diff(symbols) > 1):
# input is discontinous
return False
return True
def fit(self, obs, **kwargs):
"""Estimate model parameters.
An initialization step is performed before entering the EM
algorithm. If you want to avoid this step, pass proper
``init_params`` keyword argument to estimator's constructor.
Parameters
----------
obs : list
List of array-like observation sequences, each of which
has shape (n_i, n_features), where n_i is the length of
the i_th observation.
"""
err_msg = ("Input must be both positive integer array and "
"every element must be continuous, but %s was given.")
if not self._check_input_symbols(obs):
raise ValueError(err_msg % obs)
return _BaseHMM.fit(self, obs, **kwargs)
class GMMHMM(_BaseHMM):
"""Hidden Markov Model with Gaussin mixture emissions
.. warning::
The HMM module and its functions will be removed in 0.17
as it no longer falls within the project's scope and API.
Attributes
----------
n_components : int
Number of states in the model.
transmat : array, shape (`n_components`, `n_components`)
Matrix of transition probabilities between states.
startprob : array, shape ('n_components`,)
Initial state occupation distribution.
gmms : array of GMM objects, length `n_components`
GMM emission distributions for each state.
random_state : RandomState or an int seed (0 by default)
A random number generator instance
n_iter : int, optional
Number of iterations to perform.
thresh : float, optional
Convergence threshold.
init_params : string, optional
Controls which parameters are initialized prior to training.
Can contain any combination of 's' for startprob, 't' for transmat, 'm'
for means, 'c' for covars, and 'w' for GMM mixing weights. Defaults to
all parameters.
params : string, optional
Controls which parameters are updated in the training process. Can
contain any combination of 's' for startprob, 't' for transmat,
'm' for means, and 'c' for covars, and 'w' for GMM mixing weights.
Defaults to all parameters.
Examples
--------
>>> from sklearn.hmm import GMMHMM
>>> GMMHMM(n_components=2, n_mix=10, covariance_type='diag')
... # doctest: +ELLIPSIS, +NORMALIZE_WHITESPACE
GMMHMM(algorithm='viterbi', covariance_type='diag',...
See Also
--------
GaussianHMM : HMM with Gaussian emissions
"""
def __init__(self, n_components=1, n_mix=1, startprob=None, transmat=None,
startprob_prior=None, transmat_prior=None,
algorithm="viterbi", gmms=None, covariance_type='diag',
covars_prior=1e-2, random_state=None, n_iter=10, thresh=1e-2,
params=string.ascii_letters,
init_params=string.ascii_letters):
"""Create a hidden Markov model with GMM emissions.
Parameters
----------
n_components : int
Number of states.
"""
_BaseHMM.__init__(self, n_components, startprob, transmat,
startprob_prior=startprob_prior,
transmat_prior=transmat_prior,
algorithm=algorithm,
random_state=random_state,
n_iter=n_iter,
thresh=thresh,
params=params,
init_params=init_params)
# XXX: Hotfit for n_mix that is incompatible with the scikit's
# BaseEstimator API
self.n_mix = n_mix
self._covariance_type = covariance_type
self.covars_prior = covars_prior
self.gmms = gmms
if gmms is None:
gmms = []
for x in range(self.n_components):
if covariance_type is None:
g = GMM(n_mix)
else:
g = GMM(n_mix, covariance_type=covariance_type)
gmms.append(g)
self.gmms_ = gmms
# Read-only properties.
@property
def covariance_type(self):
"""Covariance type of the model.
Must be one of 'spherical', 'tied', 'diag', 'full'.
"""
return self._covariance_type
def _compute_log_likelihood(self, obs):
return np.array([g.score(obs) for g in self.gmms_]).T
def _generate_sample_from_state(self, state, random_state=None):
return self.gmms_[state].sample(1, random_state=random_state).flatten()
def _init(self, obs, params='stwmc'):
super(GMMHMM, self)._init(obs, params=params)
allobs = np.concatenate(obs, 0)
for g in self.gmms_:
g.set_params(init_params=params, n_iter=0)
g.fit(allobs)
def _initialize_sufficient_statistics(self):
stats = super(GMMHMM, self)._initialize_sufficient_statistics()
stats['norm'] = [np.zeros(g.weights_.shape) for g in self.gmms_]
stats['means'] = [np.zeros(np.shape(g.means_)) for g in self.gmms_]
stats['covars'] = [np.zeros(np.shape(g.covars_)) for g in self.gmms_]
return stats
def _accumulate_sufficient_statistics(self, stats, obs, framelogprob,
posteriors, fwdlattice, bwdlattice,
params):
super(GMMHMM, self)._accumulate_sufficient_statistics(
stats, obs, framelogprob, posteriors, fwdlattice, bwdlattice,
params)
for state, g in enumerate(self.gmms_):
_, lgmm_posteriors = g.score_samples(obs)
lgmm_posteriors += np.log(posteriors[:, state][:, np.newaxis]
+ np.finfo(np.float).eps)
gmm_posteriors = np.exp(lgmm_posteriors)
tmp_gmm = GMM(g.n_components, covariance_type=g.covariance_type)
n_features = g.means_.shape[1]
tmp_gmm._set_covars(
distribute_covar_matrix_to_match_covariance_type(
np.eye(n_features), g.covariance_type,
g.n_components))
norm = tmp_gmm._do_mstep(obs, gmm_posteriors, params)
if np.any(np.isnan(tmp_gmm.covars_)):
raise ValueError
stats['norm'][state] += norm
if 'm' in params:
stats['means'][state] += tmp_gmm.means_ * norm[:, np.newaxis]
if 'c' in params:
if tmp_gmm.covariance_type == 'tied':
stats['covars'][state] += tmp_gmm.covars_ * norm.sum()
else:
cvnorm = np.copy(norm)
shape = np.ones(tmp_gmm.covars_.ndim)
shape[0] = np.shape(tmp_gmm.covars_)[0]
cvnorm.shape = shape
stats['covars'][state] += tmp_gmm.covars_ * cvnorm
def _do_mstep(self, stats, params):
super(GMMHMM, self)._do_mstep(stats, params)
# All that is left to do is to apply covars_prior to the
# parameters updated in _accumulate_sufficient_statistics.
for state, g in enumerate(self.gmms_):
n_features = g.means_.shape[1]
norm = stats['norm'][state]
if 'w' in params:
g.weights_ = normalize(norm)
if 'm' in params:
g.means_ = stats['means'][state] / norm[:, np.newaxis]
if 'c' in params:
if g.covariance_type == 'tied':
g.covars_ = ((stats['covars'][state]
+ self.covars_prior * np.eye(n_features))
/ norm.sum())
else:
cvnorm = np.copy(norm)
shape = np.ones(g.covars_.ndim)
shape[0] = np.shape(g.covars_)[0]
cvnorm.shape = shape
if (g.covariance_type in ['spherical', 'diag']):
g.covars_ = (stats['covars'][state] +
self.covars_prior) / cvnorm
elif g.covariance_type == 'full':
eye = np.eye(n_features)
g.covars_ = ((stats['covars'][state]
+ self.covars_prior * eye[np.newaxis])
/ cvnorm)