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Learnability in Online Kernel Selection with Memory Constraint via Data-dependent Regret Analysis

Machine Learning 2025-03-25 v3

Abstract

Online kernel selection is a fundamental problem of online kernel methods.In this paper,we study online kernel selection with memory constraint in which the memory of kernel selection and online prediction procedures is limited to a fixed budget. An essential question is what is the intrinsic relationship among online learnability, memory constraint, and data complexity? To answer the question,it is necessary to show the trade-offs between regret and memory constraint.Previous work gives a worst-case lower bound depending on the data size,and shows learning is impossible within a small memory constraint.In contrast, we present distinct results by offering data-dependent upper bounds that rely on two data complexities:kernel alignment and the cumulative losses of competitive hypothesis.We propose an algorithmic framework giving data-dependent upper bounds for two types of loss functions.For the hinge loss function,our algorithm achieves an expected upper bound depending on kernel alignment.For smooth loss functions,our algorithm achieves a high-probability upper bound depending on the cumulative losses of competitive hypothesis.We also prove a matching lower bound for smooth loss functions.Our results show that if the two data complexities are sub-linear,then learning is possible within a small memory constraint.Our algorithmic framework depends on a new buffer maintaining framework and a reduction from online kernel selection to prediction with expert advice. Finally,we empirically verify the prediction performance of our algorithms on benchmark datasets.

Keywords

Cite

@article{arxiv.2407.00916,
  title  = {Learnability in Online Kernel Selection with Memory Constraint via Data-dependent Regret Analysis},
  author = {Junfan Li and Shizhong Liao},
  journal= {arXiv preprint arXiv:2407.00916},
  year   = {2025}
}
R2 v1 2026-06-28T17:24:22.450Z