English

Scalable Mean-Field Variational Inference via Preconditioned Primal-Dual Optimization

Machine Learning 2026-02-11 v2 Machine Learning

Abstract

In this work, we investigate the large-scale mean-field variational inference (MFVI) problem from a mini-batch primal-dual perspective. By reformulating MFVI as a constrained finite-sum problem, we develop a novel primal-dual algorithm based on an augmented Lagrangian formulation, termed primal-dual variational inference (PD-VI). PD-VI jointly updates global and local variational parameters in the evidence lower bound in a scalable manner. To further account for heterogeneous loss geometry across different variational parameter blocks, we introduce a block-preconditioned extension, P2^2D-VI, which adapts the primal-dual updates to the geometry of each parameter block and improves both numerical robustness and practical efficiency. We establish convergence guarantees for both PD-VI and P2^2D-VI under properly chosen constant step size, without relying on conjugacy assumptions or explicit bounded-variance conditions. In particular, we prove O(1/T)O(1/T) convergence to a stationary point in general settings and linear convergence under strong convexity. Numerical experiments on synthetic data and a real large-scale spatial transcriptomics dataset demonstrate that our methods consistently outperform existing stochastic variational inference approaches in terms of convergence speed and solution quality.

Keywords

Cite

@article{arxiv.2602.07632,
  title  = {Scalable Mean-Field Variational Inference via Preconditioned Primal-Dual Optimization},
  author = {Jinhua Lyu and Tianmin Yu and Ying Ma and Naichen Shi},
  journal= {arXiv preprint arXiv:2602.07632},
  year   = {2026}
}
R2 v1 2026-07-01T10:26:05.996Z