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Main Authors: Mayala, Moria, Wintenberger, Olivier, Tillier, Charles, Dombry, Clément
Format: Preprint
Published: 2024
Subjects:
Online Access:https://arxiv.org/abs/2408.01777
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author Mayala, Moria
Wintenberger, Olivier
Tillier, Charles
Dombry, Clément
author_facet Mayala, Moria
Wintenberger, Olivier
Tillier, Charles
Dombry, Clément
contents We study predictive probability inference in classification tasks using random forests under class imbalance. We focus on two simplified variants of Breiman's algorithm, namely subsampling Infinite Random Forests (IRFs) and under-sampling IRFs, and establish their asymptotic normality. In the under-sampling setting, training data from both classes are resampled to achieve balance, which enhances minority class representation but introduces a biased model. To correct this, we propose a debiasing procedure based on Importance Sampling (IS) using odds ratios. We instantiate our results using 1-Nearest Neighbor (1-NN) classifiers as base learners in the IRFs and prove the nearly minimax optimality of the approach for Lipschitz continuous objectives. We also show that the IS bagged 1-NN estimator matches the convergence rate of its subsampled counterpart while attaining lower asymptotic variance in most cases. Our theoretical findings are supported by simulation studies, highlighting the empirical benefits of the proposed approach.
format Preprint
id arxiv_https___arxiv_org_abs_2408_01777
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Infinite random forests for imbalanced classification tasks
Mayala, Moria
Wintenberger, Olivier
Tillier, Charles
Dombry, Clément
Statistics Theory
We study predictive probability inference in classification tasks using random forests under class imbalance. We focus on two simplified variants of Breiman's algorithm, namely subsampling Infinite Random Forests (IRFs) and under-sampling IRFs, and establish their asymptotic normality. In the under-sampling setting, training data from both classes are resampled to achieve balance, which enhances minority class representation but introduces a biased model. To correct this, we propose a debiasing procedure based on Importance Sampling (IS) using odds ratios. We instantiate our results using 1-Nearest Neighbor (1-NN) classifiers as base learners in the IRFs and prove the nearly minimax optimality of the approach for Lipschitz continuous objectives. We also show that the IS bagged 1-NN estimator matches the convergence rate of its subsampled counterpart while attaining lower asymptotic variance in most cases. Our theoretical findings are supported by simulation studies, highlighting the empirical benefits of the proposed approach.
title Infinite random forests for imbalanced classification tasks
topic Statistics Theory
url https://arxiv.org/abs/2408.01777