Expectation-Maximization¶
Expectation-Maximization (EM) algorithm is an iterative method for finding the maximum likelihood and maximum a posteriori estimates of parameters in models that typically depend on hidden variables.
While serving as a clustering technique, EM is also used in non-linear dimensionality reduction, missing value problems, and other areas.
Details¶
Given a set \(X\) of \(n\) feature vectors \(x_1 = (x_{11}, \ldots, x_{1p}), \ldots, x_n = (x_{n1}, \ldots, x_{np})\) of dimension \(p\), the problem is to find a maximum-likelihood estimate of the parameters of the underlying distribution when the data is incomplete or has missing values.
Expectation-Maximization (EM) Algorithm in the General Form¶
Let \(X\) be the observed data which has log-likelihood \(l(\theta; X)\) depending on the parameters \(\theta\). Let \(X^m\) be the latent or missing data, so that \(T=(X, X^m)\) is the complete data with log-likelihood \(l_0(\theta; X)\). The algorithm for solving the problem in its general form is the following EM algorithm ([Dempster77], [Hastie2009]):
Choose initial values of the parameters \(\theta^{(0)}\).
Expectation step: in the \(j\)-th step, compute \(Q(\theta', \theta^{(j)}) = E (l_0(\theta'; T) | X, \theta^{(j)})\) as a function of the dummy argument \(\theta'\).
Maximization step: in the \(j\)-th step, calculate the new estimate \(\theta^{(j+1)}\) by maximizing \(Q(\theta', \theta^{(j)})\) over \(\theta'\).
Repeat steps 2 and 3 until convergence.
EM algorithm for the Gaussian Mixture Model¶
Gaussian Mixture Model (GMM) is a mixture of k p-dimensional multivariate Gaussian distributions represented as
where \(\sum _{i=1}^{k}{\alpha_i} = 1\) and \(\alpha_i \geq 0\).
The \(pd(x|\theta_i)\) is the probability density function with parameters \(\theta_i = (m_i, \Sigma_i)\), where \(m_i\) the vector of means, and \(\Sigma_i\) is the variance-covariance matrix. The probability density function for a \(p\)-dimensional multivariate Gaussian distribution is defined as follows:
Let \(x_{ij} = I\{x_i \text{belongs to j mixture component}\}\) be the indicator function and \(\theta = (\alpha_1, \ldots, \alpha_k; \theta_1, \ldots, \theta_k)\).
Computation¶
The EM algorithm for GMM includes the following steps:
Define the weights as follows:
for \(i = 1, \ldots, n\) and \(j=1, \ldots, k\).
Choose initial values of the parameters: \({\theta }^{\left(0\right)}=\left({\alpha }_{1}^{\left(0\right)},...,{\alpha }_{k}^{\left(0\right)};{\theta }_{1}^{\left(0\right)},...,{\theta }_{k}^{\left(0\right)}\right)\)
Expectation step: in the \(j\)-th step, compute the matrix \(W = {(w_{ij})}_{nxk}\) with the weights \(w_{ij}\)
Maximization step: in the \(j\)-th step, for all \(r=1, \ldots, k\) compute:
The mixture weights \({\alpha }_{r}^{\left(j+1\right)}=\frac{{n}_{r}}{n}\), where \({n}_{r}=\sum _{i=1}^{n}{w}_{ir}\) is the “amount” of the feature vectors that are assigned to the \(r\)-th mixture component
Mean estimates \({m}_{r}^{\left(j+1\right)}=\frac{1}{{n}_{r}}\sum _{i=1}^{n}{w}_{ir}{x}_{i}\)
Covariance estimate \(\sum _{r}^{(j+1)}=({\sigma }_{r,hg}^{(j+1)})\) of size \(p \times p\) with \(\sigma_{r,hg}^{(j+1)}=\frac{1}{n_r}\sum_{l=1}^{n}{w}_{lr}(x_{lh}-m_{r,h}^{(j+1)})(x_{lg}-m_{r,g}^{(j+1)})\)
Repeat steps 2 and 3 until any of these conditions is met:
\(|\log({\theta }^{(j+1)}-{\theta }^{(j)})|<\epsilon\), where the likelihood function is:
\(\log(\theta)=\sum_{i=1}^{n}\log(\sum _{j=1}^{k}{pd(x}_{i}|{z}_{j},{\theta }_{j}){\alpha }_{j})\)
The number of iterations exceeds the predefined level.
Initialization¶
The EM algorithm for GMM requires initialized vector of weights, vectors of means, and variance-covariance [Biernacki2003, Maitra2009].
The EM initialization algorithm for GMM includes the following steps:
Perform nTrials starts of the EM algorithm with nIterations iterations and start values:
Initial means - \(k\) different random observations from the input data set
Initial weights - the values of \(1/k\)
Initial covariance matrices - the covariance of the input data
Regard the result of the best EM algorithm in terms of the likelihood function values as the result of initialization
Initialization¶
The EM algorithm for GMM requires initialized vector of weights, vectors of means, and variance-covariance. Skip the initialization step if you already calculated initial weights, means, and covariance matrices.
Batch Processing¶
Algorithm Input¶
The EM for GMM initialization algorithm accepts the input
described below. Pass the Input ID
as a parameter to the methods
that provide input for your algorithm.
Input ID |
Input |
---|---|
data |
Pointer to the \(n \times p\) numeric table with the data to which the EM initialization algorithm is applied. The input can be an object of any class derived from NumericTable. |
Algorithm Parameters¶
The EM for GMM initialization algorithm has the following parameters:
Parameter |
Default Value |
Description |
---|---|---|
|
|
The floating-point type that the algorithm uses for intermediate computations. Can be |
|
|
Performance-oriented computation method, the only method supported by the algorithm. |
|
Not applicable |
The number of components in the Gaussian Mixture Model, a required parameter. |
|
\(20\) |
The number of starts of the EM algorithm. |
|
\(10\) |
The maximal number of iterations in each start of the EM algorithm. |
|
1.0e-04 |
The threshold for termination of the algorithm. |
|
|
Covariance matrix storage scheme in the Gaussian Mixture Model:
|
|
SharePtr< engines:: mt19937:: Batch>() |
Pointer to the random number generator engine that is used internally to get the initial means in each EM start. |
Algorithm Output¶
The EM for GMM initialization algorithm calculates the results described below.
Pass the Result ID
as a parameter to the methods that access the results of your algorithm.
Result ID |
Result |
---|---|
|
Pointer to the \(1 \times k\) numeric table with mixture weights. Note By default, this result is an object of the |
|
Pointer to the \(k \times p\) numeric table with each row containing the estimate of the means for the \(i\)-th mixture component, where \(i=0, 1, \ldots, k-1\). Note By default, this result is an object of the |
|
Pointer to the
Note By default, the collection contains objects of the |
Computation¶
Batch Processing¶
Algorithm Input¶
The EM for GMM algorithm accepts the input described below.
Pass the Input ID
as a parameter to the methods that provide input for your algorithm.
Input ID |
Input |
---|---|
|
Pointer to the \(n \times p\) numeric table with the data to which the EM
algorithm is applied. The input can be an object of any class derived
from |
|
Pointer to the \(1 \times k\) numeric table with initial mixture weights. This input can be an object of any class derived from NumericTable. |
|
Pointer to a \(k \times p\) numeric table. Each row in this table contains the
initial value of the means for the \(i\)-th mixture component, where \(i = 0, 1, \ldots, k-1\).
This input can be an object of any class derived from |
|
Pointer to the
The collection can contain objects of any class derived from NumericTable. |
|
Pointer to the result of the EM for GMM initialization algorithm. The result of initialization contains weights, means, and a collection of covariances. You can use this input to set the initial values for the EM for GMM algorithm instead of explicitly specifying the weights, means, and covariance collection. |
Algorithm Parameters¶
The EM for GMM algorithm has the following parameters:
Parameter |
Default Value |
Description |
---|---|---|
|
|
The floating-point type that the algorithm uses for intermediate computations. Can be |
|
|
Performance-oriented computation method, the only method supported by the algorithm. |
|
Not applicable |
The number of components in the Gaussian Mixture Model, a required parameter. |
|
\(10\) |
The maximal number of iterations in the algorithm. |
|
1.0e-04 |
The threshold for termination of the algorithm. |
|
Pointer to an object of the BatchIface class |
Pointer to the algorithm that computes the covariance matrix. Note By default, the respective oneDAL algorithm is used,
implemented in the class derived from |
|
\(0.01\) |
Factor for covariance regularization in the case of ill-conditional data. |
|
|
Covariance matrix storage scheme in the Gaussian Mixture Model:
|
Algorithm Output¶
The EM for GMM algorithm calculates the results described below. Pass
the Result ID
as a parameter to the methods that access the results
of your algorithm.
Result ID |
Result |
---|---|
|
Pointer to the \(1 \times k\) numeric table with mixture weights. Note By default, this result is an object of the |
|
Pointer to the \(k \times p\) numeric table with each row containing the estimate of the means for the \(i\)-th mixture component, where \(i=0, 1, \ldots, k-1\). Note By default, this result is an object of the |
|
Pointer to the DataCollection object that contains \(k\) numeric tables, each with the \(p \times p\) variance-covariance matrix for the \(i\)-th mixture component of size:
Note By default, the collection contains objects of the |
|
Pointer to the \(1 \times 1\) numeric table with the value of the logarithm of the likelihood function after the last iteration. Note By default, this result is an object of the |
|
Pointer to the \(1 \times 1\) numeric table with the number of iterations computed after completion of the algorithm. Note By default, this result is an object of the |
Examples¶
Batch Processing:
Batch Processing:
Performance Considerations¶
To get the best overall performance of the expectation-maximization algorithm at the initialization and computation stages:
If input data is homogeneous, provide the input data and store results in homogeneous numeric tables of the same type as specified in the algorithmFPType class template parameter.
If input data is non-homogeneous, use AOS layout rather than SOA layout.
Product and Performance Information |
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Performance varies by use, configuration and other factors. Learn more at www.Intel.com/PerformanceIndex. Notice revision #20201201 |