DPSR: Differentially Private Sparse Reconstruction via Multi-Stage Denoising for Recommender Systems
Abstract
Differential privacy (DP) has emerged as the gold standard for protecting user data in recommender systems, but existing privacy-preserving mechanisms face a fundamental challenge: the privacy-utility tradeoff inevitably degrades recommendation quality as privacy budgets tighten. We introduce DPSR (Differentially Private Sparse Reconstruction), a novel three-stage denoising framework that fundamentally addresses this limitation by exploiting the inherent structure of rating matrices -- sparsity, low-rank properties, and collaborative patterns. DPSR consists of three synergistic stages: (1) information-theoretic noise calibration that adaptively reduces noise for high-information ratings, (2) collaborative filtering-based denoising that leverages item-item similarities to remove privacy noise, and (3) low-rank matrix completion that exploits latent structure for signal recovery. Critically, all denoising operations occur after noise injection, preserving differential privacy through the post-processing immunity theorem while removing both privacy-induced and inherent data noise. Through extensive experiments on synthetic datasets with controlled ground truth, we demonstrate that DPSR achieves 5.57\% to 9.23\% RMSE improvement over state-of-the-art Laplace and Gaussian mechanisms across privacy budgets ranging from =0.1 to =10.0 (all improvements statistically significant with p < 0.05, most p < 0.001). Remarkably, at =1.0, DPSR achieves RMSE of 0.9823, outperforming even the non-private baseline (1.0983), demonstrating that our denoising pipeline acts as an effective regularizer that removes data noise in addition to privacy noise.
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