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Main Authors: Zhang, Wei-Wei, Xia, Zhuo, Zhao, Wei, Pan, Wei, Shi, Haobin
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2506.02734
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author Zhang, Wei-Wei
Xia, Zhuo
Zhao, Wei
Pan, Wei
Shi, Haobin
author_facet Zhang, Wei-Wei
Xia, Zhuo
Zhao, Wei
Pan, Wei
Shi, Haobin
contents In the NISQ era, one of the most important bottlenecks for the realization of universal quantum computation is error correction. Stabiliser code is the most recognizable type of quantum error correction code. A scalable efficient decoder is most desired for the application of the quantum error correction codes. In this work, we propose a self-attention U-Net quantum decoder (SU-NetQD) for toric code, which outperforms the minimum weight perfect matching decoder, especially in the circuit level noise environments. Specifically, with our SU-NetQD, we achieve lower logical error rates compared with MWPM and discover an increased trend of code threshold as the increase of noise bias. We obtain a high threshold of 0.231 for the extremely biased noise environment. The combination of low-level decoder and high-level decoder is the key innovation for the high accuracy of our decoder. With transfer learning mechanics, our decoder is scalable for cases with different code distances. Our decoder provides a practical tool for quantum noise analysis and promotes the practicality of quantum error correction codes and quantum computing.
format Preprint
id arxiv_https___arxiv_org_abs_2506_02734
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Self-attention U-Net decoder for toric codes
Zhang, Wei-Wei
Xia, Zhuo
Zhao, Wei
Pan, Wei
Shi, Haobin
Quantum Physics
In the NISQ era, one of the most important bottlenecks for the realization of universal quantum computation is error correction. Stabiliser code is the most recognizable type of quantum error correction code. A scalable efficient decoder is most desired for the application of the quantum error correction codes. In this work, we propose a self-attention U-Net quantum decoder (SU-NetQD) for toric code, which outperforms the minimum weight perfect matching decoder, especially in the circuit level noise environments. Specifically, with our SU-NetQD, we achieve lower logical error rates compared with MWPM and discover an increased trend of code threshold as the increase of noise bias. We obtain a high threshold of 0.231 for the extremely biased noise environment. The combination of low-level decoder and high-level decoder is the key innovation for the high accuracy of our decoder. With transfer learning mechanics, our decoder is scalable for cases with different code distances. Our decoder provides a practical tool for quantum noise analysis and promotes the practicality of quantum error correction codes and quantum computing.
title Self-attention U-Net decoder for toric codes
topic Quantum Physics
url https://arxiv.org/abs/2506.02734