Macromux: scalable postselection for high-threshold fault-tolerant quantum computation
Abstract
We introduce a new resource-efficient scheme for fault-tolerant quantum computation known as `macroscale multiplexing' (or simply `Macromux'), that utilizes scalable postselection to significantly improve the threshold of a given fault-tolerant protocol against both Pauli and erasure errors. Macromux is a hierarchical method for postselecting on constant-size space-time windows of a fault tolerant protocol, requiring only constant additional overheads. The method can be straightforwardly implemented for any fault-tolerant protocol and in any architecture that has access to routing and memory, such as linear-optical fusion-based architectures. We construct fault-tolerant protocols that, to our knowledge, have the highest thresholds in the literature; we perform simulations of fusion-based schemes based on the surface code, showing a maximum possible increase in Pauli thresholds of up to a factor of (from to ). Our schemes are highly-resource efficient, and can for example, double the loss thresholds of some photonic fusion-based protocols using as little as overhead.
Keywords
Cite
@article{arxiv.2603.04875,
title = {Macromux: scalable postselection for high-threshold fault-tolerant quantum computation},
author = {Patrick Birchall and Jacob Bridgeman and Christopher Dawson and Terry Farrelly and Yehua Liu and Naomi Nickerson and Mihir Pant and Sam Roberts and Karthik Seetharam and David Tuckett},
journal= {arXiv preprint arXiv:2603.04875},
year = {2026}
}
Comments
12+2 pages, 13 figures, comments welcome