English

Beyond Dense Connectivity: Explicit Sparsity for Scalable Recommendation

Information Retrieval 2026-04-23 v4

Abstract

Recent progress in scaling large models has motivated recommender systems to increase model depth and capacity to better leverage massive behavioral data. However, recommendation inputs are high-dimensional and extremely sparse, and simply scaling dense backbones (e.g., deep MLPs) often yields diminishing returns or even performance degradation. Our analysis of industrial CTR models reveals a phenomenon of implicit connection sparsity: most learned connection weights tend towards zero, while only a small fraction remain prominent. This indicates a structural mismatch between dense connectivity and sparse recommendation data; by compelling the model to process vast low-utility connections instead of valid signals, the dense architecture itself becomes the primary bottleneck to effective pattern modeling. We propose SSR (Explicit Sparsity for Scalable Recommendation), a framework that incorporates sparsity explicitly into the architecture. SSR employs a multi-view "filter-then-fuse" mechanism, decomposing inputs into parallel views for dimension-level sparse filtering followed by dense fusion. Specifically, we realize the sparsity via two strategies: a Static Random Filter that achieves efficient structural sparsity via fixed dimension subsets, and Iterative Competitive Sparse (ICS), a differentiable dynamic mechanism that employs bio-inspired competition to adaptively retain high-response dimensions. Experiments on three public datasets and a billion-scale industrial dataset from AliExpress (a global e-commerce platform) show that SSR outperforms state-of-the-art baselines under similar budgets. Crucially, SSR exhibits superior scalability, delivering continuous performance gains where dense models saturate.

Keywords

Cite

@article{arxiv.2604.08011,
  title  = {Beyond Dense Connectivity: Explicit Sparsity for Scalable Recommendation},
  author = {Yantao Yu and Sen Qiao and Lei Shen and Bing Wang and Xiaoyi Zeng},
  journal= {arXiv preprint arXiv:2604.08011},
  year   = {2026}
}

Comments

Accepted as a full paper at SIGIR 2026. 11 pages, 6 figures

R2 v1 2026-07-01T12:00:50.646Z