Expectation Maximization (EM) is a kind of probabilistic method to classify data. Please correct me if I am wrong if it is not a classifier.

What is an intuitive explanation of this EM technique? What is expectation here and what is being maximized?


Note: the code behind this answer can be found here.

Suppose we have some data sampled from two different groups, red and blue:

enter image description here

Here, we can see which data point belongs to the red or blue group. This makes it easy to find the parameters that characterise each group. For example, the mean of the red group is around 3, the mean of the blue group is around 7 (and we could find the exact means if we wanted).

This is, generally speaking, known as maximum likelihood estimation. Given some data, we compute the value of a parameter (or parameters) that best explains that data.

Now imagine that we cannot see which value was sampled from which group. Everything looks purple to us:

enter image description here

Here we have the knowledge that there are two groups of values, but we don't know which group any particular value belongs to.

Can we still estimate the means for the red group and blue group that best fit this data?

Yes, often we can! Expectation Maximisation gives us a way to do it. The very general idea behind the algorithm is this:

  1. Start with an initial estimate of what each parameter might be.
  2. Compute the likelihood that each parameter produces the data point.
  3. Calculate weights for each data point indicating whether it is more red or more blue based on the likelihood of it being produced by a parameter. Combine the weights with the data (expectation).
  4. Compute a better estimate for the parameters using the weight-adjusted data (maximisation).
  5. Repeat steps 2 to 4 until the parameter estimate converges (the process stops producing a different estimate).

These steps need some further explanation, so I'll walk through the problem described above.

Example: estimating mean and standard deviation

I'll use Python in this example, but the code should be fairly easy to understand if you're not familiar with this language.

Suppose we have two groups, red and blue, with the values distributed as in the image above. Specifically, each group contains a value drawn from a normal distribution with the following parameters:

import numpy as np
from scipy import stats

np.random.seed(110) # for reproducible results

# set parameters
red_mean = 3
red_std = 0.8

blue_mean = 7
blue_std = 2

# draw 20 samples from normal distributions with red/blue parameters
red = np.random.normal(red_mean, red_std, size=20)
blue = np.random.normal(blue_mean, blue_std, size=20)

both_colours = np.sort(np.concatenate((red, blue))) # for later use...

Here is an image of these red and blue groups again (to save you from having to scroll up):

enter image description here

When we can see the colour of each point (i.e. which group it belongs to), it's very easy to estimate the mean and standard deviation for each each group. We just pass the red and blue values to the builtin functions in NumPy. For example:

>>> np.mean(red)
>>> np.std(red)
>>> np.mean(blue)
>>> np.std(blue)

But what if we can't see the colours of the points? That is, instead of red or blue, every point has been coloured purple.

To try and recover the mean and standard deviation parameters for the red and blue groups, we can use Expectation Maximisation.

Our first step (step 1 above) is to guess at the parameter values for each group's mean and standard deviation. We don't have to guess intelligently; we can pick any numbers we like:

# estimates for the mean
red_mean_guess = 1.1
blue_mean_guess = 9

# estimates for the standard deviation
red_std_guess = 2
blue_std_guess = 1.7

These parameter estimates produce bell curves that look like this:

enter image description here

These are bad estimates. Both means (the vertical dotted lines) look far off any kind of "middle" for sensible groups of points, for instance. We want to improve these estimates.

The next step (step 2) is to compute the likelihood of each data point appearing under the current parameter guesses:

likelihood_of_red = stats.norm(red_mean_guess, red_std_guess).pdf(both_colours)
likelihood_of_blue = stats.norm(blue_mean_guess, blue_std_guess).pdf(both_colours)

Here, we have simply put each data point into the probability density function for a normal distribution using our current guesses at the mean and standard deviation for red and blue. This tells us, for example, that with our current guesses the data point at 1.761 is much more likely to be red (0.189) than blue (0.00003).

For each data point, we can turn these two likelihood values into weights (step 3) so that they sum to 1 as follows:

likelihood_total = likelihood_of_red + likelihood_of_blue

red_weight = likelihood_of_red / likelihood_total
blue_weight = likelihood_of_blue / likelihood_total

With our current estimates and our newly-computed weights, we can now compute new estimates for the mean and standard deviation of the red and blue groups (step 4).

We twice compute the mean and standard deviation using all data points, but with the different weightings: once for the red weights and once for the blue weights.

The key bit of intuition is that the greater the weight of a colour on a data point, the more the data point influences the next estimates for that colour's parameters. This has the effect of "pulling" the parameters in the right direction.

def estimate_mean(data, weight):
    For each data point, multiply the point by the probability it
    was drawn from the colour's distribution (its "weight").

    Divide by the total weight: essentially, we're finding where 
    the weight is centred among our data points.
    return np.sum(data * weight) / np.sum(weight)

def estimate_std(data, weight, mean):
    For each data point, multiply the point's squared difference
    from a mean value by the probability it was drawn from
    that distribution (its "weight").

    Divide by the total weight: essentially, we're finding where 
    the weight is centred among the values for the difference of
    each data point from the mean.

    This is the estimate of the variance, take the positive square
    root to find the standard deviation.
    variance = np.sum(weight * (data - mean)**2) / np.sum(weight)
    return np.sqrt(variance)

# new estimates for standard deviation
blue_std_guess = estimate_std(both_colours, blue_weight, blue_mean_guess)
red_std_guess = estimate_std(both_colours, red_weight, red_mean_guess)

# new estimates for mean
red_mean_guess = estimate_mean(both_colours, red_weight)
blue_mean_guess = estimate_mean(both_colours, blue_weight)

We have new estimates for the parameters. To improve them again, we can jump back to step 2 and repeat the process. We do this until the estimates converge, or after some number of iterations have been performed (step 5).

For our data, the first five iterations of this process look like this (recent iterations have stronger appearance):

enter image description here

We see that the means are already converging on some values, and the shapes of the curves (governed by the standard deviation) are also becoming more stable.

If we continue for 20 iterations, we end up with the following:

enter image description here

The EM process has converged to the following values, which turn out to very close to the actual values (where we can see the colours - no hidden variables):

          | EM guess | Actual |  Delta
Red mean  |    2.910 |  2.802 |  0.108
Red std   |    0.854 |  0.871 | -0.017
Blue mean |    6.838 |  6.932 | -0.094
Blue std  |    2.227 |  2.195 |  0.032

In the code above you may have noticed that the new estimation for standard deviation was computed using the previous iteration's estimate for the mean. Ultimately it does not matter if we compute a new value for the mean first as we are just finding the (weighted) variance of values around some central point. We will still see the estimates for the parameters converge.

| improve this answer | |
  • what if we even dont know the number of normal distributions from which this is coming from? Here you have taken an example of k=2 distributions, can we also estimate k, and the k parameter sets? – stackit Aug 3 '17 at 14:22
  • 1
    @stackit: I'm not sure there's a straightforward general way to compute the most likely value of k as part of the EM process in this case. The main issue is that we would need to start EM with estimates for each of parameters we want to find, and that entails that we need to know/estimate k before we begin. It is possible, however, to estimate the proportion of points belonging to a group via EM here. Maybe if we overestimate k, the proportion of all but two of the groups would drop to near zero. I haven't experimented with this, so I don't know how well it would work in practice. – Alex Riley Aug 5 '17 at 9:28
  • 1
    @AlexRiley Can you say a bit more about the formulas for computing the new mean and standard deviation estimates? – Lemon Jan 18 '18 at 13:03
  • 3
    @AlexRiley Thanks for the explanation. Why are the new standard deviation estimates calculated using the old guess of the mean? What if the new estimates of the mean are found first? – GoodDeeds Mar 2 '18 at 20:59
  • 1
    @Lemon GoodDeeds Kaushal - apologies for my late reply to your questions. I've tried to edit the answer to address the points you've raised. I have also made all of the code used in this answer accessible in a notebook here (which also includes more details explanations of some points I touched upon). – Alex Riley Jul 20 '18 at 17:41

EM is an algorithm for maximizing a likelihood function when some of the variables in your model are unobserved (i.e. when you have latent variables).

You might fairly ask, if we're just trying to maximize a function, why don't we just use the existing machinery for maximizing a function. Well, if you try to maximize this by taking derivatives and setting them to zero, you find that in many cases the first-order conditions don't have a solution. There's a chicken-and-egg problem in that to solve for your model parameters you need to know the distribution of your unobserved data; but the distribution of your unobserved data is a function of your model parameters.

E-M tries to get around this by iteratively guessing a distribution for the unobserved data, then estimating the model parameters by maximizing something that is a lower bound on the actual likelihood function, and repeating until convergence:

The EM algorithm

Start with guess for values of your model parameters

E-step: For each datapoint that has missing values, use your model equation to solve for the distribution of the missing data given your current guess of the model parameters and given the observed data (note that you are solving for a distribution for each missing value, not for the expected value). Now that we have a distribution for each missing value, we can calculate the expectation of the likelihood function with respect to the unobserved variables. If our guess for the model parameter was correct, this expected likelihood will be the actual likelihood of our observed data; if the parameters were not correct, it will just be a lower bound.

M-step: Now that we've got an expected likelihood function with no unobserved variables in it, maximize the function as you would in the fully observed case, to get a new estimate of your model parameters.

Repeat until convergence.

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  • 6
    I do not understand your E-step. Part of the problem is that as I am learning this stuff, I can't find people who use the same terminology. So what do you mean by model equation? I don't know what you mean by solving for a probability distribution? – user678392 Jun 25 '13 at 23:58

Here is a straight-forward recipe to understand the Expectation Maximisation algorithm:

1- Read this EM tutorial paper by Do and Batzoglou.

2- You may have question marks in your head, have a look at the explanations on this maths stack exchange page.

3- Look at this code that I wrote in Python that explains the example in the EM tutorial paper of item 1:

Warning : The code may be messy/suboptimal, since I am not a Python developer. But it does the job.

import numpy as np
import math

#### E-M Coin Toss Example as given in the EM tutorial paper by Do and Batzoglou* #### 

def get_mn_log_likelihood(obs,probs):
    """ Return the (log)likelihood of obs, given the probs"""
    # Multinomial Distribution Log PMF
    # ln (pdf)      =             multinomial coeff            *   product of probabilities
    # ln[f(x|n, p)] = [ln(n!) - (ln(x1!)+ln(x2!)+...+ln(xk!))] + [x1*ln(p1)+x2*ln(p2)+...+xk*ln(pk)]     

    multinomial_coeff_denom= 0
    prod_probs = 0
    for x in range(0,len(obs)): # loop through state counts in each observation
        multinomial_coeff_denom = multinomial_coeff_denom + math.log(math.factorial(obs[x]))
        prod_probs = prod_probs + obs[x]*math.log(probs[x])

    multinomial_coeff = math.log(math.factorial(sum(obs))) -  multinomial_coeff_denom
    likelihood = multinomial_coeff + prod_probs
    return likelihood

# 1st:  Coin B, {HTTTHHTHTH}, 5H,5T
# 2nd:  Coin A, {HHHHTHHHHH}, 9H,1T
# 3rd:  Coin A, {HTHHHHHTHH}, 8H,2T
# 4th:  Coin B, {HTHTTTHHTT}, 4H,6T
# 5th:  Coin A, {THHHTHHHTH}, 7H,3T
# so, from MLE: pA(heads) = 0.80 and pB(heads)=0.45

# represent the experiments
head_counts = np.array([5,9,8,4,7])
tail_counts = 10-head_counts
experiments = zip(head_counts,tail_counts)

# initialise the pA(heads) and pB(heads)
pA_heads = np.zeros(100); pA_heads[0] = 0.60
pB_heads = np.zeros(100); pB_heads[0] = 0.50

# E-M begins!
delta = 0.001  
j = 0 # iteration counter
improvement = float('inf')
while (improvement>delta):
    expectation_A = np.zeros((5,2), dtype=float) 
    expectation_B = np.zeros((5,2), dtype=float)
    for i in range(0,len(experiments)):
        e = experiments[i] # i'th experiment
        ll_A = get_mn_log_likelihood(e,np.array([pA_heads[j],1-pA_heads[j]])) # loglikelihood of e given coin A
        ll_B = get_mn_log_likelihood(e,np.array([pB_heads[j],1-pB_heads[j]])) # loglikelihood of e given coin B

        weightA = math.exp(ll_A) / ( math.exp(ll_A) + math.exp(ll_B) ) # corresponding weight of A proportional to likelihood of A 
        weightB = math.exp(ll_B) / ( math.exp(ll_A) + math.exp(ll_B) ) # corresponding weight of B proportional to likelihood of B                            

        expectation_A[i] = np.dot(weightA, e) 
        expectation_B[i] = np.dot(weightB, e)

    pA_heads[j+1] = sum(expectation_A)[0] / sum(sum(expectation_A)); 
    pB_heads[j+1] = sum(expectation_B)[0] / sum(sum(expectation_B)); 

    improvement = max( abs(np.array([pA_heads[j+1],pB_heads[j+1]]) - np.array([pA_heads[j],pB_heads[j]]) ))
    j = j+1
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  • I find that your program will result in both A and B to 0.66, I also implement it using scala, also find that the result is 0.66, can you help check that ? – zjffdu Nov 9 '13 at 11:09
  • Using a spreadsheet, I only find your 0.66 results if my initial guesses are equal. Otherwise, I can reproduce the output of the tutorial. – soakley Nov 12 '13 at 18:07
  • @zjffdu, how many iterations does the EM run before returning you 0.66? If you initialise with equal values it may be getting stuck at a local maximum and you will see that the number of iterations is extremely low (since there is no improvement). – Zhubarb Nov 13 '13 at 10:00
  • You can also check out this slide by Andrew Ng and Harvard's course note – Minh Phan Jan 27 '18 at 11:09

Technically the term "EM" is a bit underspecified, but I assume you refer to the Gaussian Mixture Modelling cluster analysis technique, that is an instance of the general EM principle.

Actually, EM cluster analysis is not a classifier. I know that some people consider clustering to be "unsupervised classification", but actually cluster analysis is something quite different.

The key difference, and the big misunderstanding classification people always have with cluster analysis is that: in cluster analaysis, there is no "correct solution". It is a knowledge discovery method, it is actually meant to find something new! This makes evaluation very tricky. It is often evaluated using a known classification as reference, but that is not always appropriate: the classification you have may or may not reflect what is in the data.

Let me give you an example: you have a large data set of customers, including gender data. A method that splits this data set into "male" and "female" is optimal when you compare it with the existing classes. In a "prediction" way of thinking this is good, as for new users you could now predict their gender. In a "knowledge discovery" way of thinking this is actually bad, because you wanted to discover some new structure in the data. A method that would e.g. split the data into elderly people and kids however would score as worse as it can get with respect to the male/female class. However, that would be an excellent clustering result (if the age wasn't given).

Now back to EM. Essentially it assumes that your data is composed of multiple multivariate normal distributions (note that this is a very strong assumption, in particular when you fix the number of clusters!). It then tries to find a local optimal model for this by alternatingly improving the model and the object assignment to the model.

For best results in a classification context, choose the number of clusters larger than the number of classes, or even apply the clustering to single classes only (to find out whether there is some structure within the class!).

Say you want to train a classifier to tell apart "cars", "bikes" and "trucks". There is little use in assuming the data to consist of exactly 3 normal distributions. However, you may assume that there is more than one type of cars (and trucks and bikes). So instead of training a classifier for these three classes, you cluster cars, trucks and bikes into 10 clusters each (or maybe 10 cars, 3 trucks and 3 bikes, whatever), then train a classifier to tell apart these 30 classes, and then merge the class result back to the original classes. You may also discover that there is one cluster that is particularly hard to classify, for example Trikes. They're somewhat cars, and somewhat bikes. Or delivery trucks, that are more like oversized cars than trucks.

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  • how is EM underspecified? – sam boosalis Apr 12 '13 at 17:12
  • There is more than one version of it. Technically, you can call Lloyd style k-means "EM", too. You need to specify what model you use. – Has QUIT--Anony-Mousse Apr 13 '13 at 1:28

Other answers being good, i will try to provide another perspective and tackle the intuitive part of the question.

EM (Expectation-Maximization) algorithm is a variant of a class of iterative algorithms using duality

Excerpt (emphasis mine):

In mathematics, a duality, generally speaking, translates concepts, theorems or mathematical structures into other concepts, theorems or structures, in a one-to-one fashion, often (but not always) by means of an involution operation: if the dual of A is B, then the dual of B is A. Such involutions sometimes have fixed points, so that the dual of A is A itself

Usually a dual B of an object A is related to A in some way that preserves some symmetry or compatibility. For example AB = const

Examples of iterative algorithms, employing duality (in the previous sense) are:

  1. Euclidean algorithm for Greatest Common Divisor, and its variants
  2. Gram–Schmidt Vector Basis algorithm and variants
  3. Arithmetic Mean - Geometric Mean Inequality, and its variants
  4. Expectation-Maximization algorithm and its variants (see also here for an information-geometric view)
  5. (.. other similar algorithms..)

In a similar fashion, the EM algorithm can also be seen as two dual maximization steps:

..[EM] is seen as maximizing a joint function of the parameters and of the distribution over the unobserved variables.. The E-step maximizes this function with respect to the distribution over the unobserved variables; the M-step with respect to the parameters..

In an iterative algorithm using duality there is the explicit (or implicit) assumption of an equilibrium (or fixed) point of convergence (for EM this is proved using Jensen's inequality)

So the outline of such algorithms is:

  1. E-like step: Find best solution x with respect to given y being held constant.
  2. M-like step (dual): Find best solution y with respect to x (as computed in previous step) being held constant.
  3. Criterion of Termination/Convergence step: Repeat steps 1, 2 with the updated values of x,y until convergence (or specified number of iterations is reached)

Note that when such an algorithm converges to a (global) optimum, it has found a configuration which is best in both senses (i.e in both the x domain/parameters and the y domain/parameters). However the algorithm can just find a local optimum and not the global optimum.

i would say this is the intuitive description of the outline of the algorithm

For the statistical arguments and applications, other answers have given good explanations (check also references in this answer)

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The accepted answer references the Chuong EM Paper, which does a decent job explaining EM. There is also a youtube video that explains the paper in more detail.

To recap, here is the scenario:

1st:  {H,T,T,T,H,H,T,H,T,H} 5 Heads, 5 Tails; Did coin A or B generate me?
2nd:  {H,H,H,H,T,H,H,H,H,H} 9 Heads, 1 Tails
3rd:  {H,T,H,H,H,H,H,T,H,H} 8 Heads, 2 Tails
4th:  {H,T,H,T,T,T,H,H,T,T} 4 Heads, 6 Tails
5th:  {T,H,H,H,T,H,H,H,T,H} 7 Heads, 3 Tails

Two possible coins, A & B are used to generate these distributions.
A & B have an unknown parameter: their bias towards heads.

We don't know the biases, but we can simply start with a guess: A=60% heads, B=50% heads.

In the case of the first trial's question, intuitively we'd think B generated it since the proportion of heads matches B's bias very well... but that value was just a guess, so we can't be sure.

With that in mind, I like to think of the EM solution like this:

  • Each trial of flips gets to 'vote' on which coin it likes the most
    • This is based on how well each coin fits its distribution
    • OR, from the point of view of the coin, there is high expectation of seeing this trial relative to the other coin (based on log likelihoods).
  • Depending on how much each trial likes each coin, it can update the guess of that coin's parameter (bias).
    • The more a trial likes a coin, the more it gets to update the coin's bias to reflect its own!
    • Essentially the coin's biases are updated by combining these weighted updates across all trials, a process called (maximazation), which refers to trying to get the best guesses for each coin's bias given a set of trials.

This may be an oversimplification (or even fundamentally wrong on some levels), but I hope this helps on an intuitive level!

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EM is used to maximize the likelihood of a model Q with latent variables Z.

It's an iterative optimization.

theta <- initial guess for hidden parameters
while not converged:
    Q(theta'|theta) = E[log L(theta|Z)]
    theta <- argmax_theta' Q(theta'|theta)

e-step: given current estimation of Z calculate the expected loglikelihood function

m-step: find theta which maximizes this Q

GMM Example:

e-step: estimate label assignments for each datapoint given the current gmm-parameter estimation

m-step: maximize a new theta given the new label assigments

K-means is also an EM algorithm and there is a lot of explaining animations on K-means.

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Using the same article by Do and Batzoglou cited in Zhubarb's answer, I implemented EM for that problem in Java. The comments to his answer show that the algorithm gets stuck at a local optimum, which also occurs with my implementation if the parameters thetaA and thetaB are the same.

Below is the standard output of my code, showing the convergence of the parameters.

thetaA = 0.71301, thetaB = 0.58134
thetaA = 0.74529, thetaB = 0.56926
thetaA = 0.76810, thetaB = 0.54954
thetaA = 0.78316, thetaB = 0.53462
thetaA = 0.79106, thetaB = 0.52628
thetaA = 0.79453, thetaB = 0.52239
thetaA = 0.79593, thetaB = 0.52073
thetaA = 0.79647, thetaB = 0.52005
thetaA = 0.79667, thetaB = 0.51977
thetaA = 0.79674, thetaB = 0.51966
thetaA = 0.79677, thetaB = 0.51961
thetaA = 0.79678, thetaB = 0.51960
thetaA = 0.79679, thetaB = 0.51959
Final result:
thetaA = 0.79678, thetaB = 0.51960

Below is my Java implementation of EM to solve the problem in (Do and Batzoglou, 2008). The core part of the implementation is the loop to run EM until the parameters converge.

private Parameters _parameters;

public Parameters run()
    while (true)

        Parameters estimatedParameters = maximization();

        if (_parameters.converged(estimatedParameters)) {

        _parameters = estimatedParameters;

    return _parameters;

Below is the entire code.

import java.util.*;

This class encapsulates the parameters of the problem. For this problem posed
in the article by (Do and Batzoglou, 2008), the parameters are thetaA and
thetaB, the probability of a coin coming up heads for the two coins A and B,
class Parameters
    double _thetaA = 0.0; // Probability of heads for coin A.
    double _thetaB = 0.0; // Probability of heads for coin B.

    double _delta = 0.00001;

    public Parameters(double thetaA, double thetaB)
        _thetaA = thetaA;
        _thetaB = thetaB;

    Returns true if this parameter is close enough to another parameter
    (typically the estimated parameter coming from the maximization step).
    public boolean converged(Parameters other)
        if (Math.abs(_thetaA - other._thetaA) < _delta &&
            Math.abs(_thetaB - other._thetaB) < _delta)
            return true;

        return false;

    public double getThetaA()
        return _thetaA;

    public double getThetaB()
        return _thetaB;

    public String toString()
        return String.format("thetaA = %.5f, thetaB = %.5f", _thetaA, _thetaB);


This class encapsulates an observation, that is the number of heads
and tails in a trial. The observation can be either (1) one of the
experimental observations, or (2) an estimated observation resulting from
the expectation step.
class Observation
    double _numHeads = 0;
    double _numTails = 0;

    public Observation(String s)
        for (int i = 0; i < s.length(); i++)
            char c = s.charAt(i);

            if (c == 'H')
            else if (c == 'T')
                throw new RuntimeException("Unknown character: " + c);

    public Observation(double numHeads, double numTails)
        _numHeads = numHeads;
        _numTails = numTails;

    public double getNumHeads()
        return _numHeads;

    public double getNumTails()
        return _numTails;

    public String toString()
        return String.format("heads: %.1f, tails: %.1f", _numHeads, _numTails);


This class runs expectation-maximization for the problem posed by the article
from (Do and Batzoglou, 2008).
public class EM
    // Current estimated parameters.
    private Parameters _parameters;

    // Observations from the trials. These observations are set once.
    private final List<Observation> _observations;

    // Estimated observations per coin. These observations are the output
    // of the expectation step.
    private List<Observation> _expectedObservationsForCoinA;
    private List<Observation> _expectedObservationsForCoinB;

    private static java.io.PrintStream o = System.out;

    Principal constructor.
    @param observations The observations from the trial.
    @param parameters The initial guessed parameters.
    public EM(List<Observation> observations, Parameters parameters)
        _observations = observations;
        _parameters = parameters;

    Run EM until parameters converge.
    public Parameters run()

        while (true)

            Parameters estimatedParameters = maximization();

            o.printf("%s\n", estimatedParameters);

            if (_parameters.converged(estimatedParameters)) {

            _parameters = estimatedParameters;

        return _parameters;


    Given the observations and current estimated parameters, compute new
    estimated completions (distribution over the classes) and observations.
    private void expectation()

        _expectedObservationsForCoinA = new ArrayList<Observation>();
        _expectedObservationsForCoinB = new ArrayList<Observation>();

        for (Observation observation : _observations)
            int numHeads = (int)observation.getNumHeads();
            int numTails = (int)observation.getNumTails();

            double probabilityOfObservationForCoinA=
                binomialProbability(10, numHeads, _parameters.getThetaA());

            double probabilityOfObservationForCoinB=
                binomialProbability(10, numHeads, _parameters.getThetaB());

            double normalizer = probabilityOfObservationForCoinA +

            // Compute the completions for coin A and B (i.e. the probability
            // distribution of the two classes, summed to 1.0).

            double completionCoinA = probabilityOfObservationForCoinA /
            double completionCoinB = probabilityOfObservationForCoinB /

            // Compute new expected observations for the two coins.

            Observation expectedObservationForCoinA =
                new Observation(numHeads * completionCoinA,
                                numTails * completionCoinA);

            Observation expectedObservationForCoinB =
                new Observation(numHeads * completionCoinB,
                                numTails * completionCoinB);


    Given new estimated observations, compute new estimated parameters.
    private Parameters maximization()

        double sumCoinAHeads = 0.0;
        double sumCoinATails = 0.0;
        double sumCoinBHeads = 0.0;
        double sumCoinBTails = 0.0;

        for (Observation observation : _expectedObservationsForCoinA)
            sumCoinAHeads += observation.getNumHeads();
            sumCoinATails += observation.getNumTails();

        for (Observation observation : _expectedObservationsForCoinB)
            sumCoinBHeads += observation.getNumHeads();
            sumCoinBTails += observation.getNumTails();

        return new Parameters(sumCoinAHeads / (sumCoinAHeads + sumCoinATails),
                              sumCoinBHeads / (sumCoinBHeads + sumCoinBTails));

        //o.printf("parameters: %s\n", _parameters);


    Since the coin-toss experiment posed in this article is a Bernoulli trial,
    use a binomial probability Pr(X=k; n,p) = (n choose k) * p^k * (1-p)^(n-k).
    private static double binomialProbability(int n, int k, double p)
        double q = 1.0 - p;
        return nChooseK(n, k) * Math.pow(p, k) * Math.pow(q, n-k);

    private static long nChooseK(int n, int k)
        long numerator = 1;

        for (int i = 0; i < k; i++)
            numerator = numerator * n;

        long denominator = factorial(k);

        return (long)(numerator / denominator);

    private static long factorial(int n)
        long result = 1;
        for (; n >0; n--)
            result = result * n;

        return result;

    Entry point into the program.
    public static void main(String argv[])
        // Create the observations and initial parameter guess
        // from the (Do and Batzoglou, 2008) article.

        List<Observation> observations = new ArrayList<Observation>();
        observations.add(new Observation("HTTTHHTHTH"));
        observations.add(new Observation("HHHHTHHHHH"));
        observations.add(new Observation("HTHHHHHTHH"));
        observations.add(new Observation("HTHTTTHHTT"));
        observations.add(new Observation("THHHTHHHTH"));

        Parameters initialParameters = new Parameters(0.6, 0.5);

        EM em = new EM(observations, initialParameters);

        Parameters finalParameters = em.run();

        o.printf("Final result:\n%s\n", finalParameters);
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