English

Network-Integrated Decoding System for Real-Time Quantum Error Correction with Lattice Surgery

Quantum Physics 2025-04-17 v1 Distributed, Parallel, and Cluster Computing Networking and Internet Architecture

Abstract

Existing real-time decoders for surface codes are limited to isolated logical qubits and do not support logical operations involving multiple logical qubits. We present DECONET, a first-of-its-kind decoding system that scales to thousands of logical qubits and supports logical operations implemented through lattice surgery. DECONET organizes compute resources in a network-integrated hybrid tree-grid structure, which results in minimal latency increase and no throughput degradation as the system grows. Specifically, DECONET can be scaled to any arbitrary number of ll logical qubits by increasing the compute resources by O(l×log(l))O(l \times log(l)), which provides the required O(l)O(l) growth in I/O resources while incurring only an O(log(l))O(log(l)) increase in latency-a modest growth that is sufficient for thousands of logical qubits. Moreover, we analytically show that the scaling approach preserves throughput, keeping DECONET backlog-free for any number of logical qubits. We report an exploratory prototype of DECONET, called DECONET/HELIOS, built with five VMK-180 FPGAs, that successfully decodes 100 logical qubits of distance five. For 100 logical qubits, under a phenomenological noise rate of 0.1%, the DECONET/HELIOS has an average latency of 2.40 {\mu}s and an inverse throughput of 0.84 {\mu}s per measurement round.

Keywords

Cite

@article{arxiv.2504.11805,
  title  = {Network-Integrated Decoding System for Real-Time Quantum Error Correction with Lattice Surgery},
  author = {Namitha Liyanage and Yue Wu and Emmet Houghton and Lin Zhong},
  journal= {arXiv preprint arXiv:2504.11805},
  year   = {2025}
}
R2 v1 2026-06-28T23:00:05.241Z