Variational Combinatorial Sequential Monte Carlo for Bayesian Phylogenetics in Hyperbolic Space
Abstract
Hyperbolic space naturally encodes hierarchical structures such as phylogenies (binary trees), where inward-bending geodesics reflect paths through least common ancestors, and the exponential growth of neighborhoods mirrors the super-exponential scaling of topologies. This scaling challenge limits the efficiency of Euclidean-based approximate inference methods. Motivated by the geometric connections between trees and hyperbolic space, we develop novel hyperbolic extensions of two sequential search algorithms: Combinatorial and Nested Combinatorial Sequential Monte Carlo (\textsc{Csmc} and \textsc{Ncsmc}). Our approach introduces consistent and unbiased estimators, along with variational inference methods (\textsc{H-Vcsmc} and \textsc{H-Vncsmc}), which outperform their Euclidean counterparts. Empirical results demonstrate improved speed, scalability and performance in high-dimensional phylogenetic inference tasks.
Keywords
Cite
@article{arxiv.2501.17965,
title = {Variational Combinatorial Sequential Monte Carlo for Bayesian Phylogenetics in Hyperbolic Space},
author = {Alex Chen and Philipe Chlenski and Kenneth Munyuza and Antonio Khalil Moretti and Christian A. Naesseth and Itsik Pe'er},
journal= {arXiv preprint arXiv:2501.17965},
year = {2025}
}
Comments
24 pages, 10 figures