Efficient classical sampling from Gaussian boson sampling distributions on unweighted graphs

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Yexin Zhang, Shuo Zhou, Xinzhao Wang, Ziruo Wang, Ziyi Yang, Rui Yang, Yecheng Xue, Tongyang Li

Published: 22 Oct 2025, Last Modified: 10 Apr 2026Nature CommunicationsEveryoneRevisionsCC BY-SA 4.0
Abstract: Gaussian Boson Sampling (GBS) is a promising candidate for demonstrating quantum computational advantage and can be applied to solving graph-related problems. In this work, we propose Markov chain Monte Carlo-based algorithms to sample from GBS distributions on undirected, unweighted graphs. Our main contribution is a double-loop variant of Glauber dynamics, whose stationary distribution matches the GBS distribution. We further prove that it mixes in polynomial time for dense graphs using a refined canonical path argument. Numerically, we conduct experiments on unweighted graphs with 256 vertices, larger than the scales in former GBS experiments as well as classical simulations. In particular, we show that both the single-loop and double-loop Glauber dynamics improve the performance of original random search and simulated annealing algorithms for the max-Hafnian and densest k-subgraph problems up to 10 ×. Overall, our approach offers both theoretical guarantees and practical advantages for efficient classical sampling from GBS distributions on unweighted graphs. The authors propose Markov chain Monte Carlo algorithms to sample from GBS distributions on unweighted graphs, and prove that it mixes in polynomial time for dense graphs. Numerical experiments on 256-vertex graphs are conducted, demonstrating that the algorithm improves the performance up to 10x.