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Additive Logistic Regression: a Statistical View of Boosting

Additive Logistic Regression: a Statistical View of Boosting. J. Friedman, T. Hastie, & R. Tibshirani Journal of Statistics. Outline. Introduction A brief history of boosting Additive Models AdaBoost – an Additive logistic regression model Simulation studies. Discrete AdaBoost.

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Additive Logistic Regression: a Statistical View of Boosting

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  1. Additive Logistic Regression:a Statistical View of Boosting J. Friedman, T. Hastie, & R. Tibshirani Journal of Statistics

  2. Outline • Introduction • A brief history of boosting • Additive Models • AdaBoost – an Additive logistic regression model • Simulation studies

  3. Discrete AdaBoost

  4. Performance of Discrete AdaBoost

  5. Re-sampling in AdaBoost • Connection with bagging • Bagging is a variance reduction technique. • Is Boosting also a variance reduction technique? • Boosting performs comparably well when: • Weighted tree-growing algorithm rather than weighted resampling. • Removing the randomizatoin component. • Stumps • Have low variance but high bias • Boosting is capable of both bias and variance reduction.

  6. Real AdaBoost

  7. Statistical Interpretation of the AdaBoost • Fitting an additive model by minimizing squared-error loss in a forward stagewise manner. • At the mth stage, fix • Minimize squared error to obtain • AdaBoost fits an additive model using a criterion similar to, but not the same as, the binomial log-likelihood • Better loss function for classification

  8. A brief history of boosting • The first simple boosting procedure is developed in the PAC-learning framework. • Strength of Weak Learnability • After learning an initial classifier h1on the first N training points. • h2 is learned on a new sample of N points, half of which are misclassified by h1. • h3 is learned on N points for which h1 and h2 disagree. • The boosted classifier is hB = Majority Vote(h1, h2, h3)

  9. Additive Models • Addtive regression models • Extended additive models • Classification problems

  10. Additive Regression Models • Modeling the mean • The additive model: • There is a separate function for each of the p input variables xj. • Backfitting algorithm • A modular “Gauss-Seidel” algorithm for fitting additive models • Backfitting update • Backfitting cycles are repeated until convergence • Backfitting converges to the minimizer of under fairly general conditions.

  11. Extended Additive Models (1) • Additive models whose elements are functions of potentially all of the input features x. • If we set • Generalized backfitting algorithm • Updates • Greedy forward stepwise approach

  12. Extended Additive Models (2) • Algorithm for fitting a single weak leaner to data • In the forward stepwise procedure • This can be viewed as a procudure for boosting a weak learner to form a powerful commttee

  13. Classification problems • Additive logistic regression • Inverting • These models are usually fit by maximizing the binomial log-likelihood.

  14. AdaBoost – an Additive Logistic Regression Model • AdaBoost can be interpreted as stage-wise estimation procedures for fitting an additive logistic regression model • AdaBoost optimize an exponential criterion which to second order is equivalent to the binomial log-likelihood criterion • Proposing a more standard likelihood-based boosting procedure

  15. An Exponential Criterion (1) • Minimizing the criterion • The function F(x) that minimizes J(F) is the symmetric logistic transform of P(y=1|x). • Can be proved by setting the derivative to zero

  16. An Exponential Criterion (2) • The usual logistic model • The Discrete AdaBoost algorithm (population version) builds an additive logistic regression model via Newton-like update for minimizing

  17. Derivation (a) , where For c > 0, minimizing (a) is equivalent to maximizing

  18. Continued… The solution is Note that Minimizing a quadratic approximation to the critetrion leads to a weighted least-sqares choice of f(x). Minimizing J(F+cf) to determine c: where,

  19. Update for F(x) Since The function and weight updates are of an identical form to those used in Discrete AdaBoost

  20. Corollary • After each update to the weights, the weighted misclassification error of the most recent weak learner is 50% • Weights are updated to make the new weighted problem maximally difficult for the next weak learner

  21. Derivation • The Real AdaBoost algorithm fits an additive logistic regression model by stage-wise and approximate optimization of Dividing through by And setting the derivative w.r.t f(x) to zero

  22. Corollary • At the optimal F(x), the weighted conditional mean of y is 0.

  23. Why Ee-yF(x)? • The populbation minimizer of and coincide.

  24. Losses as Approximations to Misclassification Error

  25. Direct optimization of the binomial log-likelihood • Fitting additive logistic regression models by stage-wise optimization of the Bernoulli log-likelihood.

  26. Derivation of LogitBoost (1) Newton update ,where

  27. Derivation of LogitBoost (2) • Equivalently, the Newton update f(x) solves the weighted least-squares approximation to the log-likelihood

  28. Optimizing Ee-yF(x) by Newton stepping • Proposing the “Gentle AdaBoost” procedure that instead takes adaptive Newton steps much like the LogitBoost algorithm just described

  29. Derivation • The Gentle AdaBoost algorithm uses Newton steps for minimizing Ee-yF(x) . • Newton update

  30. Comparison with Real AdaBoost • Update in Gentle AdaBoost • Update in Real AdaBoost • Log-ratios can be numerically unstable, leading to very large updates in pure regions. • Empirical evidence suggests that this more conservative algorithm has similar performance to both the Real AdaBoost and LogitBoost algorightms.

  31. Simulation Studies • Four boosting methods compared here • DAB: Discrete AdaBoost • RAB: Real AdaBoost • LB: LogitBoost • GAB: Gentle AdaBoost

  32. Data Generation • All of the simulated examples involve fairly complex decision boundaries • Ten input features randomly drawn from a 10-dim. standard normal dist. • Approximately 1000 training observations in each class • 10000 observations for test set. • Averaged over 10 such indepently drawn training/test set combinations. C1 C2 C3

  33. Additive Decision Boundary (1)

  34. Additive Decision Boundary (2)

  35. Additive Decision Boundary (3)

  36. Boosting Trees with 8-terminal nodes

  37. Analysis • Optimal decision boundary for the above examples is also additive in the original features, with • For RAG, GAB, and LB the error rate using the bigger trees is in fact 33% higher than that for stumps at 800 iterations, even though the former is four times more complex. • Non-additive decision boundaries • Boosting stumps would be less advantageous than using larger trees.

  38. Non-additive Decision Boundaries • Higher order basis functions provide the possibility to more accurately estimate those decision boundaries with high order interaction. • Data generation • 2 classes • 5000 training observations drawn from a 10-dim normal dist. • Class labels were randomly assigned to each observation with log-odds

  39. Non-additive Decision Boundaries (2)

  40. Non-additive Decision Boundaries (3)

  41. Analysis • Boosting stumps can sometimes be superior to using larger trees when decision boundaries can be closely approximated by functions that are additive in the original predictor features.

  42. Some experiments with Real World Data • UC-Irvine machine learning archive + a popular simulated dataset. • The real data examples fail to demonstrate performance differences between the various boosting methods.

  43. Additive Logistic Trees • ANOVA decomposition • Allowing the base classifier to produce higher order interactions can reduce the accuracy of the final boosted model. • Higher order interactions are produced by deeper trees. • Maximum depth becomes a “meta-parameter” of the procedure to be estimated by some model selection technique, such as cross-validation.

  44. Additive Logistic Trees (2) • Growing trees until a maximum number M of terminal nodes are induced. • “Additive logistic trees” (ALT) • Combination of truncated best-first trees, with boosting. • Another advantage of low order approximations is model visualization

  45. Weight Trimming • Trainig observations with weight wi less than a threshold • Observations deleted at a particular iteration may therefore re-enter at later iterations. • LogitBoost sometimes gives an advantage with weight trimming • Weights measre nearness to the currently estimated decision boundary • For the other three procedures the weight is monotone in • Subsample passed to the base learner can be highly unbalanced

  46. The test error for the letter recognition problem

  47. Further Generalizations of Boosting • The Newton step can be replaced by a gradient step, slowing down the fitting procedure. • Reducing susceptibility to overfitting • Any smooth loss function can be used.

  48. Concluding Remarks • Bagging, randomized trees • “Variance” reducing techniques • Boosting • Appears tobe mainly a “bias” reducing procedure. • Boosting seems resistant to overfitting • As the LogitBoost iterations proceed, the overall impact of changes introcued by fm(x) reduces. • The stage-wise nature of the boosting algorithms does not allow the full collection of parameters to be jointly fit, and thus has far lower variance than the full parameterization might suggest. • Classifiers are hurt less by overfitting than other function estimators

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