Law of Large Numbers for Bayesian two-layer Neural Network trained with Variational Inference
Descours, Arnaud, Huix, Tom, Guillin, Arnaud, Michel, Manon, Moulines, Éric, Nectoux, Boris
We provide a rigorous analysis of training by variational inference (VI) of Bayesian neural networks in the two-layer and infinite-width case. We consider a regression problem with a regularized evidence lower bound (ELBO) which is decomposed into the expected log-likelihood of the data and the Kullback-Leibler (KL) divergence between the a priori distribution and the variational posterior. With an appropriate weighting of the KL, we prove a law of large numbers for three different training schemes: (i) the idealized case with exact estimation of a multiple Gaussian integral from the reparametrization trick, (ii) a minibatch scheme using Monte Carlo sampling, commonly known as Bayes by Backprop, and (iii) a new and computationally cheaper algorithm which we introduce as Minimal VI. An important result is that all methods converge to the same mean-field limit. Finally, we illustrate our results numerically and discuss the need for the derivation of a central limit theorem.
Jul-10-2023
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- New York > New York County
- New York City (0.04)
- Rhode Island > Providence County
- Europe > France
- Hauts-de-France > Nord > Lille (0.04)
- North America > United States
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- Research Report > New Finding (0.34)
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