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Variational Bayesian Phylogenetic Inference with Semi-implicit Branch Length Distributions

Machine Learning 2024-08-12 v1 Machine Learning

Abstract

Reconstructing the evolutionary history relating a collection of molecular sequences is the main subject of modern Bayesian phylogenetic inference. However, the commonly used Markov chain Monte Carlo methods can be inefficient due to the complicated space of phylogenetic trees, especially when the number of sequences is large. An alternative approach is variational Bayesian phylogenetic inference (VBPI) which transforms the inference problem into an optimization problem. While effective, the default diagonal lognormal approximation for the branch lengths of the tree used in VBPI is often insufficient to capture the complexity of the exact posterior. In this work, we propose a more flexible family of branch length variational posteriors based on semi-implicit hierarchical distributions using graph neural networks. We show that this semi-implicit construction emits straightforward permutation equivariant distributions, and therefore can handle the non-Euclidean branch length space across different tree topologies with ease. To deal with the intractable marginal probability of semi-implicit variational distributions, we develop several alternative lower bounds for stochastic optimization. We demonstrate the effectiveness of our proposed method over baseline methods on benchmark data examples, in terms of both marginal likelihood estimation and branch length posterior approximation.

Keywords

Cite

@article{arxiv.2408.05058,
  title  = {Variational Bayesian Phylogenetic Inference with Semi-implicit Branch Length Distributions},
  author = {Tianyu Xie and Frederick A. Matsen and Marc A. Suchard and Cheng Zhang},
  journal= {arXiv preprint arXiv:2408.05058},
  year   = {2024}
}

Comments

26 pages, 7 figures

R2 v1 2026-06-28T18:08:37.721Z