Simplified Quantum Weight Reduction with Optimal Bounds
Abstract
Quantum weight reduction is the task of transforming a quantum code with large check weight into one with small check weight. Low-weight codes are essential for implementing quantum error correction on physical hardware, since high-weight measurements cannot be executed reliably. Weight reduction also serves as a critical theoretical tool, which may be relevant to the quantum PCP conjecture. We introduce a new procedure for quantum weight reduction that combines geometric insights with coning techniques, which simplifies Hastings' previous approach while achieving better parameters. Given an arbitrary quantum code with weight , our method produces a code with parameters with check weight and qubit weight . When applied to random dense CSS codes, our procedure yields explicit quantum codes that surpass the square-root distance barrier, achieving parameters . Furthermore, these codes admit a three-dimensional embedding that saturates the Bravyi-Poulin-Terhal (BPT) bound. As a further application, our weight reduction technique improves fault-tolerant logical operator measurements by reducing the number of ancilla qubits.
Cite
@article{arxiv.2510.09601,
title = {Simplified Quantum Weight Reduction with Optimal Bounds},
author = {Min-Hsiu Hsieh and Xingjian Li and Ting-Chun Lin},
journal= {arXiv preprint arXiv:2510.09601},
year = {2025}
}