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Leveraging Sparsity for Sample-Efficient Preference Learning: A Theoretical Perspective

Machine Learning 2025-06-05 v4

Abstract

This paper considers the sample-efficiency of preference learning, which models and predicts human choices based on comparative judgments. The minimax optimal estimation error rate Θ(d/n)\Theta(d/n) in classical estimation theory requires that the number of samples nn scales linearly with the dimensionality of the feature space dd. However, the high dimensionality of the feature space and the high cost of collecting human-annotated data challenge the efficiency of traditional estimation methods. To remedy this, we leverage sparsity in the preference model and establish sharp error rates. We show that under the sparse random utility model, where the parameter of the reward function is kk-sparse, the minimax optimal rate can be reduced to Θ(k/nlog(d/k))\Theta(k/n \log(d/k)). Furthermore, we analyze the 1\ell_{1}-regularized estimator and show that it achieves near-optimal rate under mild assumptions on the Gram matrix. Experiments on synthetic data and LLM alignment data validate our theoretical findings, showing that sparsity-aware methods significantly reduce sample complexity and improve prediction accuracy.

Keywords

Cite

@article{arxiv.2501.18282,
  title  = {Leveraging Sparsity for Sample-Efficient Preference Learning: A Theoretical Perspective},
  author = {Yunzhen Yao and Lie He and Michael Gastpar},
  journal= {arXiv preprint arXiv:2501.18282},
  year   = {2025}
}
R2 v1 2026-06-28T21:25:25.101Z