DReS: Dual Reconstruction Smoothing for Functional Regularization
Abstract
Smoothness is a key inductive bias in machine learning and is closely related to generalization. Existing smoothness-inducing methods typically rely either on explicit gradient regularization, which often incurs substantial computational and memory overhead, or on data-mixing strategies, which are less naturally applicable to unsupervised and self-supervised settings. In this work, we propose (DReS), a nonparametric regularization framework that induces smoothness through a spline-based auxiliary branch with shared model parameters. The method introduces no additional trainable parameters and can be applied to arbitrary submodules, making it suitable for unsupervised, self-supervised, and supervised regimes. We show theoretically that the discrepancy between the target function and its DReS approximation is controlled by higher-order smoothness quantities of the function, establishing the method as an implicit higher-order smoothness regularizer. Empirically, DReS improves representation learning across several self-supervised methods, improves generation quality in generative modeling, and achieves strong performance relative to competitive baselines in supervised learning.
Cite
@article{arxiv.2510.00253,
title = {DReS: Dual Reconstruction Smoothing for Functional Regularization},
author = {Parsa Moradi and Tayyebeh Jahaninezhad and Hanzaleh Akbarinodehi and Mohammad Ali Maddah-Ali},
journal= {arXiv preprint arXiv:2510.00253},
year = {2026}
}