English

Generalization Bounds for Semi-supervised Matrix Completion with Distributional Side Information

Machine Learning 2025-11-24 v2 Machine Learning

Abstract

We study a matrix completion problem where both the ground truth RR matrix and the unknown sampling distribution PP over observed entries are low-rank matrices, and \textit{share a common subspace}. We assume that a large amount MM of \textit{unlabeled} data drawn from the sampling distribution PP is available, together with a small amount NN of labeled data drawn from the same distribution and noisy estimates of the corresponding ground truth entries. This setting is inspired by recommender systems scenarios where the unlabeled data corresponds to `implicit feedback' (consisting in interactions such as purchase, click, etc. ) and the labeled data corresponds to the `explicit feedback', consisting of interactions where the user has given an explicit rating to the item. Leveraging powerful results from the theory of low-rank subspace recovery, together with classic generalization bounds for matrix completion models, we show error bounds consisting of a sum of two error terms scaling as O~(ndM)\widetilde{O}\left(\sqrt{\frac{nd}{M}}\right) and O~(drN)\widetilde{O}\left(\sqrt{\frac{dr}{N}}\right) respectively, where dd is the rank of PP and rr is the rank of MM. In synthetic experiments, we confirm that the true generalization error naturally splits into independent error terms corresponding to the estimations of PP and and the ground truth matrix \ground\ground respectively. In real-life experiments on Douban and MovieLens with most explicit ratings removed, we demonstrate that the method can outperform baselines relying only on the explicit ratings, demonstrating that our assumptions provide a valid toy theoretical setting to study the interaction between explicit and implicit feedbacks in recommender systems.

Keywords

Cite

@article{arxiv.2511.13049,
  title  = {Generalization Bounds for Semi-supervised Matrix Completion with Distributional Side Information},
  author = {Antoine Ledent and Mun Chong Soo and Nong Minh Hieu},
  journal= {arXiv preprint arXiv:2511.13049},
  year   = {2025}
}

Comments

Accepted at AAAI 2026

R2 v1 2026-07-01T07:40:36.507Z