English

ADELIA: Automatic Differentiation for Efficient Laplace Inference Approximations

Distributed, Parallel, and Cluster Computing 2026-05-08 v1 Performance

Abstract

Spatio-temporal Bayesian inference drives environmental and health sciences using latent Gaussian models. Integrated Nested Laplace Approximations (INLA) enable inference for these models at HPC scale but rely on derivative-based optimization over dd hyperparameters. State-of-the-art INLA implementations approximate derivatives via central finite differences (FD), requiring 2d+12d{+}1 evaluations. These evaluations are embarrassingly parallel, but total work and energy grow with dd, limiting time-to-solution under fixed budgets. Reverse-mode automatic differentiation (AD) computes exact gradients independently of dd, but its efficient application to INLA's structured-sparse kernels is an open challenge. We present ADELIA, the first AD-enabled INLA implementation with a structure-exploiting multi-GPU backward pass leveraging model sparsity. We evaluate ADELIA on ten benchmark models, including real-world air-pollution monitoring. We achieve 4.24.2--7.9×7.9\times per-gradient speedups and reliable convergence on production-scale models with up to 1.9M latent variables, where FD struggles. Even when scaled to 16--32 GPUs to match ADELIA's wall-clock time, FD consumes 55--8×8\times more energy.

Keywords

Cite

@article{arxiv.2605.06392,
  title  = {ADELIA: Automatic Differentiation for Efficient Laplace Inference Approximations},
  author = {Afif Boudaoud and Lisa Gaedke-Merzhäuser and Alexandros Nikolaos Ziogas and Vincent Maillou and Alexandru Calotoiu and Marcin Copik and Håvard Rue and Mathieu Luisier and Torsten Hoefler},
  journal= {arXiv preprint arXiv:2605.06392},
  year   = {2026}
}
R2 v1 2026-07-01T12:55:17.082Z