Soft margins for AdaBoost

G. Rätsch; T. Onoda; K. R. Müller

doi:10.1023/A:1007618119488

Soft margins for AdaBoost

G. Rätsch, T. Onoda, K. R. Müller

Research output: Contribution to journal › Article › peer-review

1145 Citations (Scopus)

Abstract

Recently ensemble methods like ADABOOST have been applied successfully in many problems, while seemingly defying the problems of overfitting. ADABOOST rarely overfits in the low noise regime, however, we show that it clearly does so for higher noise levels. Central to the understanding of this fact is the margin distribution. ADABOOST can be viewed as a constraint gradient descent in an error function with respect to the margin. We find that ADABOOST asymptotically achieves a hard margin distribution, i.e. the algorithm concentrates its resources on a few hard-to-learn patterns that are interestingly very similar to Support Vectors. A hard margin is clearly a sub-optimal strategy in the noisy case, and regularization, in our case a 'mistrust' in the data, must be introduced in the algorithm to alleviate the distortions that single difficult patterns (e.g. outliers) can cause to the margin distribution. We propose several regularization methods and generalizations of the original ADABOOST algorithm to achieve a soft margin. In particular we suggest (1) regularized ADABOOST_REG where the gradient decent is done directly with respect to the soft margin and (2) regularized linear and quadratic programming (LP/QP-) ADABOOST, where the soft margin is attained by introducing slack variables. Extensive simulations demonstrate that the proposed regularized ADABOOST-type algorithms are useful and yield competitive results for noisy data.

Original language	English
Pages (from-to)	287-320
Number of pages	34
Journal	Machine Learning
Volume	42
Issue number	3
DOIs	https://doi.org/10.1023/A:1007618119488
Publication status	Published - 2001 Mar

Bibliographical note

Funding Information:
We thank for valuable discussions with B. Schölkopf, A. Smola, T. Frieß, D. Schuurmans and B. Williamson. Partial funding from EC STORM project number 25387 is gratefully acknowledged. Furthermore, we acknowledge the referees for valuable comments.

ASJC Scopus subject areas

Software
Artificial Intelligence

Access to Document

10.1023/A:1007618119488

Cite this

@article{a909c8d006204e1ebd06845c24fc403a,

title = "Soft margins for AdaBoost",

abstract = "Recently ensemble methods like ADABOOST have been applied successfully in many problems, while seemingly defying the problems of overfitting. ADABOOST rarely overfits in the low noise regime, however, we show that it clearly does so for higher noise levels. Central to the understanding of this fact is the margin distribution. ADABOOST can be viewed as a constraint gradient descent in an error function with respect to the margin. We find that ADABOOST asymptotically achieves a hard margin distribution, i.e. the algorithm concentrates its resources on a few hard-to-learn patterns that are interestingly very similar to Support Vectors. A hard margin is clearly a sub-optimal strategy in the noisy case, and regularization, in our case a 'mistrust' in the data, must be introduced in the algorithm to alleviate the distortions that single difficult patterns (e.g. outliers) can cause to the margin distribution. We propose several regularization methods and generalizations of the original ADABOOST algorithm to achieve a soft margin. In particular we suggest (1) regularized ADABOOSTREG where the gradient decent is done directly with respect to the soft margin and (2) regularized linear and quadratic programming (LP/QP-) ADABOOST, where the soft margin is attained by introducing slack variables. Extensive simulations demonstrate that the proposed regularized ADABOOST-type algorithms are useful and yield competitive results for noisy data.",

author = "G. R{\"a}tsch and T. Onoda and M{\"u}ller, {K. R.}",

note = "Funding Information: We thank for valuable discussions with B. Sch{\"o}lkopf, A. Smola, T. Frie{\ss}, D. Schuurmans and B. Williamson. Partial funding from EC STORM project number 25387 is gratefully acknowledged. Furthermore, we acknowledge the referees for valuable comments.",

year = "2001",

month = mar,

doi = "10.1023/A:1007618119488",

language = "English",

volume = "42",

pages = "287--320",

journal = "Machine Learning",

issn = "0885-6125",

publisher = "Springer Netherlands",

number = "3",

}

TY - JOUR

T1 - Soft margins for AdaBoost

AU - Rätsch, G.

AU - Onoda, T.

AU - Müller, K. R.

N1 - Funding Information: We thank for valuable discussions with B. Schölkopf, A. Smola, T. Frieß, D. Schuurmans and B. Williamson. Partial funding from EC STORM project number 25387 is gratefully acknowledged. Furthermore, we acknowledge the referees for valuable comments.

PY - 2001/3

Y1 - 2001/3

N2 - Recently ensemble methods like ADABOOST have been applied successfully in many problems, while seemingly defying the problems of overfitting. ADABOOST rarely overfits in the low noise regime, however, we show that it clearly does so for higher noise levels. Central to the understanding of this fact is the margin distribution. ADABOOST can be viewed as a constraint gradient descent in an error function with respect to the margin. We find that ADABOOST asymptotically achieves a hard margin distribution, i.e. the algorithm concentrates its resources on a few hard-to-learn patterns that are interestingly very similar to Support Vectors. A hard margin is clearly a sub-optimal strategy in the noisy case, and regularization, in our case a 'mistrust' in the data, must be introduced in the algorithm to alleviate the distortions that single difficult patterns (e.g. outliers) can cause to the margin distribution. We propose several regularization methods and generalizations of the original ADABOOST algorithm to achieve a soft margin. In particular we suggest (1) regularized ADABOOSTREG where the gradient decent is done directly with respect to the soft margin and (2) regularized linear and quadratic programming (LP/QP-) ADABOOST, where the soft margin is attained by introducing slack variables. Extensive simulations demonstrate that the proposed regularized ADABOOST-type algorithms are useful and yield competitive results for noisy data.

AB - Recently ensemble methods like ADABOOST have been applied successfully in many problems, while seemingly defying the problems of overfitting. ADABOOST rarely overfits in the low noise regime, however, we show that it clearly does so for higher noise levels. Central to the understanding of this fact is the margin distribution. ADABOOST can be viewed as a constraint gradient descent in an error function with respect to the margin. We find that ADABOOST asymptotically achieves a hard margin distribution, i.e. the algorithm concentrates its resources on a few hard-to-learn patterns that are interestingly very similar to Support Vectors. A hard margin is clearly a sub-optimal strategy in the noisy case, and regularization, in our case a 'mistrust' in the data, must be introduced in the algorithm to alleviate the distortions that single difficult patterns (e.g. outliers) can cause to the margin distribution. We propose several regularization methods and generalizations of the original ADABOOST algorithm to achieve a soft margin. In particular we suggest (1) regularized ADABOOSTREG where the gradient decent is done directly with respect to the soft margin and (2) regularized linear and quadratic programming (LP/QP-) ADABOOST, where the soft margin is attained by introducing slack variables. Extensive simulations demonstrate that the proposed regularized ADABOOST-type algorithms are useful and yield competitive results for noisy data.

UR - http://www.scopus.com/inward/record.url?scp=0342502195&partnerID=8YFLogxK

U2 - 10.1023/A:1007618119488

DO - 10.1023/A:1007618119488

M3 - Article

AN - SCOPUS:0342502195

SN - 0885-6125

VL - 42

SP - 287

EP - 320

JO - Machine Learning

JF - Machine Learning

IS - 3

ER -

Soft margins for AdaBoost

Abstract

Bibliographical note

ASJC Scopus subject areas

Access to Document

Other files and links

Fingerprint

Cite this