Correcting quantum errors using a classical code and one additional qubit

• URL: http://arxiv.org/abs/2510.05008v1
• Date: Mon, 06 Oct 2025 16:52:05 GMT
• Title: Correcting quantum errors using a classical code and one additional qubit
• Authors: Tenzan Araki, Joseph F. Goodwin, Zhenyu Cai,
• Abstract summary: We introduce Hadamard-based Virtual Error Correction (H-VEC), a protocol that empowers any classical bit-flip code to correct arbitrary Pauli noise.<n>H-VEC virtually filters the error channel, projecting the noise into pure Y-type errors that are subsequently corrected using the classical code's native decoding algorithm.
• Score: 0.0
• License: http://creativecommons.org/licenses/by/4.0/
• Abstract: Classical error-correcting codes are powerful but incompatible with quantum noise, which includes both bit-flips and phase-flips. We introduce Hadamard-based Virtual Error Correction (H-VEC), a protocol that empowers any classical bit-flip code to correct arbitrary Pauli noise with the addition of only a single ancilla qubit and two layers of controlled-Hadamard gates. Through classical post-processing, H-VEC virtually filters the error channel, projecting the noise into pure Y-type errors that are subsequently corrected using the classical code's native decoding algorithm. We demonstrate this by applying H-VEC to the classical repetition code. Under a code-capacity noise model, the resulting protocol not only provides full quantum protection but also achieves an exponentially stronger error suppression (in distance) than the original classical code, and even larger improvements over the surface code while using much fewer qubits, simpler checks and straight-forward decoding. H-VEC comes with a sampling overhead due to its post-processing nature. It represents a new hybrid quantum error correction and mitigation framework that redefines the trade-offs between physical hardware requirements and classical processing for error suppression.

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