Does generalization performance of $l^q$ regularization learning depend on $q$? A negative example
Abstract
-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 estimator differs in varying choices of the regularization order . In particular, leads to the LASSO estimate, while corresponds to the smooth ridge regression. This makes the order a potential tuning parameter in applications. To facilitate the use of -regularization, we intend to seek for a modeling strategy where an elaborative selection on is avoidable. In this spirit, we place our investigation within a general framework of -regularized kernel learning under a sample dependent hypothesis space (SDHS). For a designated class of kernel functions, we show that all estimators for 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 might not have a strong impact in terms of the generalization capability. From this perspective, can be arbitrarily specified, or specified merely by other no generalization criteria like smoothness, computational complexity, sparsity, etc..
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