smile.classification

Class GradientTreeBoost

java.lang.Object

smile.classification.GradientTreeBoost

All Implemented Interfaces:

Classifier<double[]>

public class GradientTreeBoost
extends Object
implements Classifier<double[]>

Gradient boosting for classification. Gradient boosting is typically used with decision trees (especially CART regression trees) of a fixed size as base learners. For this special case Friedman proposes a modification to gradient boosting method which improves the quality of fit of each base learner.

Generic gradient boosting at the t-th step would fit a regression tree to pseudo-residuals. Let J be the number of its leaves. The tree partitions the input space into J disjoint regions and predicts a constant value in each region. The parameter J controls the maximum allowed level of interaction between variables in the model. With J = 2 (decision stumps), no interaction between variables is allowed. With J = 3 the model may include effects of the interaction between up to two variables, and so on. Hastie et al. comment that typically 4 ≤ J ≤ 8 work well for boosting and results are fairly insensitive to the choice of in this range, J = 2 is insufficient for many applications, and J > 10 is unlikely to be required.

Fitting the training set too closely can lead to degradation of the model's generalization ability. Several so-called regularization techniques reduce this over-fitting effect by constraining the fitting procedure. One natural regularization parameter is the number of gradient boosting iterations T (i.e. the number of trees in the model when the base learner is a decision tree). Increasing T reduces the error on training set, but setting it too high may lead to over-fitting. An optimal value of T is often selected by monitoring prediction error on a separate validation data set.

Another regularization approach is the shrinkage which times a parameter η (called the "learning rate") to update term. Empirically it has been found that using small learning rates (such as η < 0.1) yields dramatic improvements in model's generalization ability over gradient boosting without shrinking (η = 1). However, it comes at the price of increasing computational time both during training and prediction: lower learning rate requires more iterations.

Soon after the introduction of gradient boosting Friedman proposed a minor modification to the algorithm, motivated by Breiman's bagging method. Specifically, he proposed that at each iteration of the algorithm, a base learner should be fit on a subsample of the training set drawn at random without replacement. Friedman observed a substantional improvement in gradient boosting's accuracy with this modification.

Subsample size is some constant fraction f of the size of the training set. When f = 1, the algorithm is deterministic and identical to the one described above. Smaller values of f introduce randomness into the algorithm and help prevent over-fitting, acting as a kind of regularization. The algorithm also becomes faster, because regression trees have to be fit to smaller datasets at each iteration. Typically, f is set to 0.5, meaning that one half of the training set is used to build each base learner.

Also, like in bagging, sub-sampling allows one to define an out-of-bag estimate of the prediction performance improvement by evaluating predictions on those observations which were not used in the building of the next base learner. Out-of-bag estimates help avoid the need for an independent validation dataset, but often underestimate actual performance improvement and the optimal number of iterations.

Gradient tree boosting implementations often also use regularization by limiting the minimum number of observations in trees' terminal nodes. It's used in the tree building process by ignoring any splits that lead to nodes containing fewer than this number of training set instances. Imposing this limit helps to reduce variance in predictions at leaves.

References

1. J. H. Friedman. Greedy Function Approximation: A Gradient Boosting Machine, 1999.
2. J. H. Friedman. Stochastic Gradient Boosting, 1999.

Author:

Haifeng Li

Nested Class Summary

Nested Classes

Modifier and Type	Class and Description
static class	GradientTreeBoost.Trainer Trainer for GradientTreeBoost classifiers.

Constructor Summary

Constructors

Constructor and Description
GradientTreeBoost(Attribute[] attributes, double[][] x, int[] y, int T) Constructor.
GradientTreeBoost(Attribute[] attributes, double[][] x, int[] y, int T, int J, double shrinkage, double f) Constructor.
GradientTreeBoost(double[][] x, int[] y, int T) Constructor.
GradientTreeBoost(double[][] x, int[] y, int T, int J, double shrinkage, double f) Constructor.

Method Summary

Methods

Modifier and Type	Method and Description
double[]	importance() Returns the variable importance.
int	predict(double[] x) Predicts the class label of an instance.
int	predict(double[] x, double[] posteriori) Predicts the class label of an instance and also calculate a posteriori probabilities.
int	size() Returns the number of trees in the model.
double[]	test(double[][] x, int[] y) Test the model on a validation dataset.
double[][]	test(double[][] x, int[] y, ClassificationMeasure[] measures) Test the model on a validation dataset.
void	trim(int T) Trims the tree model set to a smaller size in case of over-fitting.

Methods inherited from class java.lang.Object

clone, equals, finalize, getClass, hashCode, notify, notifyAll, toString, wait, wait, wait

Constructor Detail

GradientTreeBoost

public GradientTreeBoost(double[][] x,
                 int[] y,
                 int T)

Constructor. Learns a gradient tree boosting for classification.

Parameters:

x - the training instances.

y - the class labels.

T - the number of iterations (trees).

GradientTreeBoost

public GradientTreeBoost(double[][] x,
                 int[] y,
                 int T,
                 int J,
                 double shrinkage,
                 double f)

Constructor. Learns a gradient tree boosting for classification.

Parameters:

x - the training instances.

y - the class labels.

T - the number of iterations (trees).

J - the number of leaves in each tree.

shrinkage - the shrinkage parameter in (0, 1] controls the learning rate of procedure.

f - the sampling rate for stochastic tree boosting.

GradientTreeBoost

public GradientTreeBoost(Attribute[] attributes,
                 double[][] x,
                 int[] y,
                 int T)

Constructor. Learns a gradient tree boosting for classification.

Parameters:

attributes - the attribute properties.

x - the training instances.

y - the class labels.

T - the number of iterations (trees).

GradientTreeBoost

public GradientTreeBoost(Attribute[] attributes,
                 double[][] x,
                 int[] y,
                 int T,
                 int J,
                 double shrinkage,
                 double f)

Constructor. Learns a gradient tree boosting for classification.

Parameters:

attributes - the attribute properties.

x - the training instances.

y - the class labels.

T - the number of iterations (trees).

J - the number of leaves in each tree.

shrinkage - the shrinkage parameter in (0, 1] controls the learning rate of procedure.

f - the sampling fraction for stochastic tree boosting.

Method Detail

importance

public double[] importance()

Returns the variable importance. Every time a split of a node is made on variable the impurity criterion for the two descendent nodes is less than the parent node. Adding up the decreases for each individual variable over all trees in the forest gives a simple measure of variable importance.

Returns:

the variable importance

size

public int size()

Returns the number of trees in the model.

Returns:

the number of trees in the model

trim

public void trim(int T)

Trims the tree model set to a smaller size in case of over-fitting. Or if extra decision trees in the model don't improve the performance, we may remove them to reduce the model size and also improve the speed of prediction.

Parameters:

T - the new (smaller) size of tree model set.

predict

public int predict(double[] x)

Description copied from interface: Classifier

Predicts the class label of an instance.

Specified by:

predict in interface Classifier<double[]>

Parameters:

x - the instance to be classified.

Returns:

the predicted class label

predict

public int predict(double[] x,
          double[] posteriori)

Description copied from interface: Classifier

Predicts the class label of an instance and also calculate a posteriori probabilities. Classifiers may NOT support this method since not all classification algorithms are able to calculate such a posteriori probabilities.

Specified by:

predict in interface Classifier<double[]>

Parameters:

x - the instance to be classified.

posteriori - the array to store a posteriori probabilities on output.

Returns:

the predicted class label

test

public double[] test(double[][] x,
            int[] y)

Test the model on a validation dataset.

Parameters:

x - the test data set.

y - the test data response values.

Returns:

accuracies with first 1, 2, ..., decision trees.

test

public double[][] test(double[][] x,
              int[] y,
              ClassificationMeasure[] measures)

Test the model on a validation dataset.

Parameters:

x - the test data set.

y - the test data labels.

measures - the performance measures of classification.

Returns:

performance measures with first 1, 2, ..., decision trees.