Efficient learning of logical noise from syndrome data

TL;DR

This paper introduces a syndrome-based method for efficiently learning the logical noise channel in fault-tolerant quantum circuits, significantly reducing sample complexity compared to direct logical benchmarking.

Contribution

It extends previous phenomenological models to realistic circuit-level noise, providing a unified theoretical framework and practical estimators with provable guarantees.

Findings

Achieved orders-of-magnitude sample complexity reduction

Developed efficient estimators with theoretical guarantees

Demonstrated protocol performance on multiple circuits

Abstract

Characterizing errors in quantum circuits is essential for device calibration, yet detecting rare error events requires a large number of samples. This challenge is particularly severe in calibrating fault-tolerant, error-corrected circuits, where logical error probabilities are suppressed to higher order relative to physical noise and are therefore difficult to calibrate through direct logical measurements. Recently, Wagner et al. [PRL 130, 200601 (2023)] showed that, for phenomenological Pauli noise models, the logical channel can instead be inferred from syndrome measurement data generated during error correction. Here, we extend this framework to realistic circuit-level noise models. From a unified code-theoretic perspective and spacetime code formalism, we derive necessary and sufficient conditions for learning the logical channel from syndrome data alone and explicitly characterize the learnable degrees of freedom of circuit-level Pauli faults. Using Fourier analysis and compressed sensing, we develop efficient estimators with provable guarantees on sample complexity and computational cost. We further present an end-to-end protocol and demonstrate its performance on several syndrome-extraction circuits, achieving orders-of-magnitude sample-complexity savings over direct logical benchmarking. Our results establish syndrome-based learning as a practical approach to characterizing the logical channel in fault-tolerant quantum devices.