Realistic Simulation of Quantum Repeater with Encoding and Classical Error Correction
Abstract
Quantum repeaters are essential for scalable long-distance quantum networking. As quantum information processing moves toward fault-tolerant and error-corrected operations, it becomes increasingly important to study quantum repeaters that also move beyond raw physical entanglement and towards logical entanglement. In this paper, we implement and simulate the quantum repeater with encoding and classical error correction (QRE-CEC) protocol in SeQUeNCe, a discrete-event simulator of quantum networks. The protocol distributes logical Bell pairs, performs encoded entanglement swapping, and uses classical error correction for the decoding of entanglement swapping measurement outcomes to determine Pauli-frame corrections. For this study, we extend SeQUeNCe with a stabilizer-based backend, add support for CSS code-based encoded operations, and integrate gate, measurement, idle decoherence, and state-initialization noise models. Our simulation results show that QRE-CEC suppresses all modeled errors to the second order. Also, QRE-CEC can distribute logical Bell pairs with 0.91 fidelity over a distance of 2000 km under the parameter regimes we study. Beyond protocol-level performance evaluation, our implementation exposes practical simulator and control-plane challenges that are typically abstracted away in theoretical studies.
Cite
@article{arxiv.2605.06928,
title = {Realistic Simulation of Quantum Repeater with Encoding and Classical Error Correction},
author = {Sagar Patange and Caitao Zhan and Bikun Li and Joaquin Chung and Allen Zang and Liang Jiang and Rajkumar Kettimuthu},
journal= {arXiv preprint arXiv:2605.06928},
year = {2026}
}
Comments
11 pages, 10 figures, QCE 2026 conference