R\'enyi Pufferfish Privacy with Gaussian-based Priors: From Single Gaussian to Mixture Model

Abstract

R\'enyi Pufferfish Privacy (RPP) provides a R\'enyi divergence-based privacy framework for correlated data, but existing ∞-Wasserstein mechanisms are often conservative and sacrifice data utility. We study Gaussian mechanisms for RPP under Gaussian and Gaussian-mixture priors. For single Gaussian priors, we derive the exact R\'enyi divergence after Gaussian perturbation, obtain a relaxed closed-form sufficient condition for (α,ε)-RPP, and characterize the monotonicity of the calibrated noise with respect to the privacy budget ε and the R\'enyi order α. To handle more general non-Gaussian and multimodal priors, we approximate secret-conditioned outputs with Gaussian mixture models and introduce an optimal-transport-based sufficient condition for RPP. Experiments on three UCI datasets with statistical (RAW, MEAN) and model-output (BNN, GP) queries show that our prior-aware mechanisms consistently require less noise than a recent RPP additive-noise baseline, achieving an average noise reduction of 48.9\%. These results show that our mechanisms can substantially improve the privacy-utility trade-off under RPP.