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Does generalization performance of $l^q$ regularization learning depend on $q$? A negative example

Machine Learning 2023-06-14 v2 Machine Learning

Abstract

lql^q-regularization has been demonstrated to be an attractive technique in machine learning and statistical modeling. It attempts to improve the generalization (prediction) capability of a machine (model) through appropriately shrinking its coefficients. The shape of a lql^q estimator differs in varying choices of the regularization order qq. In particular, l1l^1 leads to the LASSO estimate, while l2l^{2} corresponds to the smooth ridge regression. This makes the order qq a potential tuning parameter in applications. To facilitate the use of lql^{q}-regularization, we intend to seek for a modeling strategy where an elaborative selection on qq is avoidable. In this spirit, we place our investigation within a general framework of lql^{q}-regularized kernel learning under a sample dependent hypothesis space (SDHS). For a designated class of kernel functions, we show that all lql^{q} estimators for 0<q<0< q < \infty attain similar generalization error bounds. These estimated bounds are almost optimal in the sense that up to a logarithmic factor, the upper and lower bounds are asymptotically identical. This finding tentatively reveals that, in some modeling contexts, the choice of qq might not have a strong impact in terms of the generalization capability. From this perspective, qq can be arbitrarily specified, or specified merely by other no generalization criteria like smoothness, computational complexity, sparsity, etc..

Keywords

Cite

@article{arxiv.1307.6616,
  title  = {Does generalization performance of $l^q$ regularization learning depend on $q$? A negative example},
  author = {Shaobo Lin and Chen Xu and Jingshan Zeng and Jian Fang},
  journal= {arXiv preprint arXiv:1307.6616},
  year   = {2023}
}

Comments

There is critical wrong in the proof

R2 v1 2026-06-22T00:57:30.975Z