Posted
Evan T. Hockings, Andrew C. Doherty, Robin Harper (Mar 03 2025).
Abstract: The performance of quantum error correction can be improved with noise-aware decoders, which are calibrated to the likelihood of physical error configurations in a device. Averaged circuit eigenvalue sampling (ACES) is a Pauli noise characterisation technique that can calibrate decoders at the scales required for fault-tolerant quantum computation. We demonstrate that ACES is practically capable of calibrating a fast correlated matching decoder, enabling noise-aware decoding, in circuit-level numerical simulations of the surface code. We find that noise-aware decoding increases the error suppression factor of the code, yielding reductions in the logical error rate that increase exponentially with the code distance. Our results indicate that noise characterisation experiments performed and processed in seconds will suffice to calibrate decoders for fault-tolerant superconducting quantum computers. This establishes the practicality and utility of noise-aware decoding for quantum error correction at scale.
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