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Predictive Power of Nearest Neighbors Algorithm under Random Perturbation

Machine Learning 2020-02-14 v1 Machine Learning

Abstract

We consider a data corruption scenario in the classical kk Nearest Neighbors (kk-NN) algorithm, that is, the testing data are randomly perturbed. Under such a scenario, the impact of corruption level on the asymptotic regret is carefully characterized. In particular, our theoretical analysis reveals a phase transition phenomenon that, when the corruption level ω\omega is below a critical order (i.e., small-ω\omega regime), the asymptotic regret remains the same; when it is beyond that order (i.e., large-ω\omega regime), the asymptotic regret deteriorates polynomially. Surprisingly, we obtain a negative result that the classical noise-injection approach will not help improve the testing performance in the beginning stage of the large-ω\omega regime, even in the level of the multiplicative constant of asymptotic regret. As a technical by-product, we prove that under different model assumptions, the pre-processed 1-NN proposed in \cite{xue2017achieving} will at most achieve a sub-optimal rate when the data dimension d>4d>4 even if kk is chosen optimally in the pre-processing step.

Keywords

Cite

@article{arxiv.2002.05304,
  title  = {Predictive Power of Nearest Neighbors Algorithm under Random Perturbation},
  author = {Yue Xing and Qifan Song and Guang Cheng},
  journal= {arXiv preprint arXiv:2002.05304},
  year   = {2020}
}
R2 v1 2026-06-23T13:40:19.178Z