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df415d7e1d
sequence type. So these changes are basically just renaming some template arguments and minor changes to some typedefs.
396 lines
17 KiB
C++
396 lines
17 KiB
C++
// The contents of this file are in the public domain. See LICENSE_FOR_EXAMPLE_PROGRAMS.txt
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/*
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This is an example illustrating the use of the machine learning
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tools for sequence labeling in the dlib C++ Library.
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The general problem addressed by these tools is the following.
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Suppose you have a set of sequences of some kind and you want to
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learn to predict a label for each element of a sequence. So for
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example, you might have a set of English sentences where each
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word is labeled with its part of speech and you want to learn a
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model which can predict the part of speech for each word in a new
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sentence.
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Central to these tools is the sequence_labeler object. It is the
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object which represents the label prediction model. In particular,
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the model used by this object is the following. Given an input
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sequence x, predict an output label sequence y such that:
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y == argmax_y dot(weight_vector, PSI(x,y))
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where PSI() is supplied by the user and defines the form of the
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model. In this example program we will define it such that we
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obtain a simple Hidden Markov Model. However, it's possible to
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define much more sophisticated models. You should take a look
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at the following papers for a few examples:
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- Hidden Markov Support Vector Machines by
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Y. Altun, I. Tsochantaridis, T. Hofmann
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- Shallow Parsing with Conditional Random Fields by
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Fei Sha and Fernando Pereira
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In the remainder of this example program we will show how to
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define your own PSI(), as well as how to learn the "weight_vector"
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parameter. Once you have these two items you will be able to
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use the sequence_labeler to predict the labels of new sequences.
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*/
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#include <iostream>
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#include "dlib/svm_threaded.h"
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#include "dlib/rand.h"
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using namespace std;
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using namespace dlib;
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/*
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In this example we will be working with a Hidden Markov Model where
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the hidden nodes and observation nodes both take on 3 different states.
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The task will be to take a sequence of observations and predict the state
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of the corresponding hidden nodes.
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*/
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const unsigned long num_label_states = 3;
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const unsigned long num_sample_states = 3;
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// ----------------------------------------------------------------------------------------
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class feature_extractor
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{
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/*
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This object is where you define your PSI(). To ensure that the argmax_y
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remains a tractable problem, the PSI(x,y) vector is actually a sum of vectors,
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each derived from the entire input sequence x but only part of the label
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sequence y. This allows the argmax_y to be efficiently solved using the
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well known Viterbi algorithm.
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*/
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public:
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// This defines the type used to represent the observed sequence. You can use
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// any type here so long as it has a .size() which returns the number of things
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// in the sequence.
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typedef std::vector<unsigned long> sequence_type;
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unsigned long num_features() const
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/*!
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ensures
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- returns the dimensionality of the PSI() feature vector.
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!*/
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{
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// Recall that we are defining a HMM. So in this case the PSI() vector
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// should have the same dimensionality as the number of parameters in the HMM.
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return num_label_states*num_label_states + num_label_states*num_sample_states;
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}
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unsigned long order() const
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/*!
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ensures
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- This object represents a Markov model on the output labels.
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This parameter defines the order of the model. That is, this
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value controls how many previous label values get to be taken
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into consideration when performing feature extraction for a
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particular element of the input sequence. Note that the runtime
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of the algorithm is exponential in the order. So don't make order
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very large.
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!*/
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{
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// In this case we are using a HMM model that only looks at the
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// previous label.
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return 1;
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}
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unsigned long num_labels() const
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/*!
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ensures
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- returns the number of possible output labels.
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!*/
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{
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return num_label_states;
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}
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template <typename feature_setter, typename EXP>
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void get_features (
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feature_setter& set_feature,
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const sequence_type& x,
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const matrix_exp<EXP>& y,
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unsigned long position
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) const
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/*!
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requires
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- EXP::type == unsigned long
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(i.e. y contains unsigned longs)
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- position < x.size()
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- y.size() == min(position, order) + 1
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- is_vector(y) == true
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- max(y) < num_labels()
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- set_feature is a function object which allows expressions of the form:
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- set_features((unsigned long)feature_index, (double)feature_value);
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- set_features((unsigned long)feature_index);
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ensures
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- for all valid i:
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- interprets y(i) as the label corresponding to x[position-i]
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- This function computes the part of PSI() corresponding to the x[position]
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element of the input sequence. Moreover, this part of PSI() is returned as
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a sparse vector by invoking set_feature(). For example, to set the feature
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with an index of 55 to the value of 1 this method would call:
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set_feature(55);
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Or equivalently:
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set_feature(55,1);
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Therefore, the first argument to set_feature is the index of the feature
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to be set while the second argument is the value the feature should take.
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Additionally, note that calling set_feature() multiple times with the same
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feature index does NOT overwrite the old value, it adds to the previous
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value. For example, if you call set_feature(55) 3 times then it will
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result in feature 55 having a value of 3.
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- This function only calls set_feature() with feature_index values < num_features()
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!*/
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{
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// Again, the features below only define a simple HMM. But in general, you can
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// use a wide variety of sophisticated feature extraction methods here.
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// Pull out an indicator feature for the type of transition between the
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// previous label and the current label.
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if (y.size() > 1)
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set_feature(y(1)*num_label_states + y(0));
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// Pull out an indicator feature for the type of observed node given
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// the current label.
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set_feature(num_label_states*num_label_states +
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y(0)*num_sample_states + x[position]);
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}
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};
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// We need to define serialize() and deserialize() for our feature extractor if we want
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// to be able to serialize and deserialize our learned models. In this case the
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// implementation is empty since our feature_extractor doesn't have any state. But you
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// might define more complex feature extractors which have state that needs to be saved.
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void serialize(const feature_extractor&, std::ostream&) {}
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void deserialize(feature_extractor&, std::istream&) {}
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// ----------------------------------------------------------------------------------------
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void make_dataset (
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const matrix<double>& transition_probabilities,
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const matrix<double>& emission_probabilities,
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std::vector<std::vector<unsigned long> >& samples,
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std::vector<std::vector<unsigned long> >& labels,
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unsigned long dataset_size
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);
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/*!
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requires
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- transition_probabilities.nr() == transition_probabilities.nc()
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- transition_probabilities.nr() == emission_probabilities.nr()
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- The rows of transition_probabilities and emission_probabilities must sum to 1.
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(i.e. sum_cols(transition_probabilities) and sum_cols(emission_probabilities)
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must evaluate to vectors of all 1s.)
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ensures
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- This function randomly samples a bunch of sequences from the HMM defined by
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transition_probabilities and emission_probabilities.
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- The HMM is defined by:
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- The probability of transitioning from hidden state H1 to H2
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is given by transition_probabilities(H1,H2).
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- The probability of a hidden state H producing an observed state
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O is given by emission_probabilities(H,O).
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- #samples.size() == #labels.size() == dataset_size
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- for all valid i:
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- #labels[i] is a randomly sampled sequence of hidden states from the
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given HMM. #samples[i] is its corresponding randomly sampled sequence
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of observed states.
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!*/
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// ----------------------------------------------------------------------------------------
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int main()
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{
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// We need a dataset to test the machine learning algorithms. So we are going to
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// define a HMM based on the following two matrices and then randomly sample a
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// set of data from it. Then we will see if the machine learning method can
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// recover the HMM model from the training data.
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matrix<double> transition_probabilities(num_label_states, num_label_states);
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transition_probabilities = 0.05, 0.90, 0.05,
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0.05, 0.05, 0.90,
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0.90, 0.05, 0.05;
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matrix<double> emission_probabilities(num_label_states,num_sample_states);
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emission_probabilities = 0.5, 0.5, 0.0,
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0.0, 0.5, 0.5,
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0.5, 0.0, 0.5;
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std::vector<std::vector<unsigned long> > samples;
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std::vector<std::vector<unsigned long> > labels;
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// sample 1000 labeled sequences from the HMM.
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make_dataset(transition_probabilities,emission_probabilities,
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samples, labels, 1000);
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// print out some of the randomly sampled sequences
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for (int i = 0; i < 10; ++i)
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{
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cout << "hidden states: " << trans(vector_to_matrix(labels[i]));
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cout << "observed states: " << trans(vector_to_matrix(samples[i]));
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cout << "******************************" << endl;
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}
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// Next we use the structural_sequence_labeling_trainer to learn our
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// prediction model based on just the samples and labels.
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structural_sequence_labeling_trainer<feature_extractor> trainer;
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// This is the common SVM C parameter. Larger values encourage the
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// trainer to attempt to fit the data exactly but might overfit.
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// In general, you determine this parameter by cross-validation.
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trainer.set_c(4);
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// This trainer can use multiple CPU cores to speed up the training.
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// So set this to the number of available CPU cores.
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trainer.set_num_threads(4);
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// Learn to do sequence labeling from the dataset
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sequence_labeler<feature_extractor> labeler = trainer.train(samples, labels);
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// Test the learned labeler on one of the training samples. In this
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// case it will give the correct sequence of labels.
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std::vector<unsigned long> predicted_labels = labeler(samples[0]);
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cout << "true hidden states: "<< trans(vector_to_matrix(labels[0]));
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cout << "predicted hidden states: "<< trans(vector_to_matrix(predicted_labels));
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// We can also do cross-validation. The confusion_matrix is defined as:
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// - confusion_matrix(T,P) == the number of times a sequence element with label T
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// was predicted to have a label of P.
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// So if all predictions are perfect then only diagonal elements of this matrix will
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// be non-zero.
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matrix<double> confusion_matrix;
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confusion_matrix = cross_validate_sequence_labeler(trainer, samples, labels, 4);
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cout << "\ncross-validation: " << endl;
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cout << confusion_matrix;
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cout << "label accuracy: "<< sum(diag(confusion_matrix))/sum(confusion_matrix) << endl;
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// In this case, the label accuracy is about 88%. At this point, we want to know if
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// the machine learning method was able to recover the HMM model from the data. So
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// to test this, we can load the true HMM model into another sequence_labeler and
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// test it out on the data and compare the results.
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matrix<double,0,1> true_hmm_model_weights = log(join_cols(reshape_to_column_vector(transition_probabilities),
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reshape_to_column_vector(emission_probabilities)));
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// With this model, labeler_true will predict the most probable set of labels
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// given an input sequence. That is, it will predict using the equation:
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// y == argmax_y dot(true_hmm_model_weights, PSI(x,y))
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sequence_labeler<feature_extractor> labeler_true(true_hmm_model_weights);
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confusion_matrix = test_sequence_labeler(labeler_true, samples, labels);
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cout << "\nTrue HMM model: " << endl;
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cout << confusion_matrix;
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cout << "label accuracy: "<< sum(diag(confusion_matrix))/sum(confusion_matrix) << endl;
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// Happily, we observe that the true model also obtains a label accuracy of 88%.
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// Finally, the labeler can be serialized to disk just like most dlib objects.
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ofstream fout("labeler.dat", ios::binary);
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serialize(labeler, fout);
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fout.close();
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// recall from disk
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ifstream fin("labeler.dat", ios::binary);
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deserialize(labeler, fin);
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}
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// ----------------------------------------------------------------------------------------
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// ----------------------------------------------------------------------------------------
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// Code for creating a bunch of random samples from our HMM.
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// ----------------------------------------------------------------------------------------
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// ----------------------------------------------------------------------------------------
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void sample_hmm (
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dlib::rand& rnd,
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const matrix<double>& transition_probabilities,
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const matrix<double>& emission_probabilities,
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unsigned long previous_label,
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unsigned long& next_label,
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unsigned long& next_sample
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)
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/*!
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requires
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- previous_label < transition_probabilities.nr()
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- transition_probabilities.nr() == transition_probabilities.nc()
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- transition_probabilities.nr() == emission_probabilities.nr()
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- The rows of transition_probabilities and emission_probabilities must sum to 1.
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(i.e. sum_cols(transition_probabilities) and sum_cols(emission_probabilities)
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must evaluate to vectors of all 1s.)
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ensures
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- This function randomly samples the HMM defined by transition_probabilities
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and emission_probabilities assuming that the previous hidden state
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was previous_label.
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- The HMM is defined by:
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- P(next_label |previous_label) == transition_probabilities(previous_label, next_label)
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- P(next_sample|next_label) == emission_probabilities (next_label, next_sample)
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- #next_label == the sampled value of the hidden state
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- #next_sample == the sampled value of the observed state
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!*/
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{
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// sample next_label
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double p = rnd.get_random_double();
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for (long c = 0; p >= 0 && c < transition_probabilities.nc(); ++c)
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{
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next_label = c;
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p -= transition_probabilities(previous_label, c);
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}
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// now sample next_sample
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p = rnd.get_random_double();
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for (long c = 0; p >= 0 && c < emission_probabilities.nc(); ++c)
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{
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next_sample = c;
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p -= emission_probabilities(next_label, c);
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}
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}
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// ----------------------------------------------------------------------------------------
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void make_dataset (
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const matrix<double>& transition_probabilities,
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const matrix<double>& emission_probabilities,
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std::vector<std::vector<unsigned long> >& samples,
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std::vector<std::vector<unsigned long> >& labels,
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unsigned long dataset_size
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)
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{
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samples.clear();
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labels.clear();
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dlib::rand rnd;
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// now randomly sample some labeled sequences from our Hidden Markov Model
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for (unsigned long iter = 0; iter < dataset_size; ++iter)
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{
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const unsigned long sequence_size = rnd.get_random_32bit_number()%20+3;
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std::vector<unsigned long> sample(sequence_size);
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std::vector<unsigned long> label(sequence_size);
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unsigned long previous_label = rnd.get_random_32bit_number()%num_label_states;
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for (unsigned long i = 0; i < sample.size(); ++i)
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{
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unsigned long next_label, next_sample;
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sample_hmm(rnd, transition_probabilities, emission_probabilities,
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previous_label, next_label, next_sample);
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label[i] = next_label;
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sample[i] = next_sample;
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previous_label = next_label;
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}
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samples.push_back(sample);
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labels.push_back(label);
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}
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}
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// ----------------------------------------------------------------------------------------
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