Enhancing Fault-Tolerant Surface Code Decoding with Iterative Lattice Reweighting
Abstract
Efficient and realistic error decoding is crucial for fault-tolerant quantum computation (FTQC) on near-term devices. While decoding is a classical post-processing task, its effectiveness depends on accurately modeling quantum noise, which is hardware-dependent. In particular, correlated bit-flip () and phase-flip () errors often arise under circuit-level noise. We introduce the Iterative Reweighting Minimum-Weight Perfect Matching (IRMWPM) decoder, which systematically incorporates such correlations to enhance quantum error correction. Our method leverages fault-detection patterns to guide reweighting: correlated and detection events are identified, and their conditional probabilities update weights on the primal and dual lattices. This iterative procedure improves handling of realistic error propagation in a hardware-agnostic yet noise-aware manner. We prove that IRMWPM converges in finite time while preserving the distance guarantee of MWPM. Numerical results under circuit-level noise show substantial improvements. For distances and physical error rates , IRMWPM reduces logical error rates by over 20x with only a few iterations. It also raises the accuracy threshold from 1% to 1.16%, making it practical for near-term real-time decoding. Extrapolated estimates suggest that to reach logical error rate , IRMWPM requires distance , while standard MWPM needs , implying a major reduction in qubit overhead.
Cite
@article{arxiv.2509.06756,
title = {Enhancing Fault-Tolerant Surface Code Decoding with Iterative Lattice Reweighting},
author = {Yi Tian and Y. Zheng and Xiaoting Wang and Ching-Yi Lai},
journal= {arXiv preprint arXiv:2509.06756},
year = {2025}
}
Comments
13 pages, 10 figures, 3 tables