Circuit-level fault tolerance of cat codes

• URL: http://arxiv.org/abs/2406.04157v1
• Date: Thu, 6 Jun 2024 15:18:25 GMT
• Title: Circuit-level fault tolerance of cat codes
• Authors: Long D. H. My, Shushen Qin, Hui Khoon Ng,
• Abstract summary: Bosonic codes offer the possibility of storing quantum information in a single infinite-dimensional physical system. Much of the current efforts in bosonic codes are on correcting only loss errors. We assess the performance of the error-correction circuits for the storage of information encoded with cat codes.
• Score: 0.0
• License: http://creativecommons.org/licenses/by/4.0/
• Abstract: Bosonic codes offer the possibility of storing quantum information in a single infinite-dimensional physical system endowed with the capability to correct errors, thereby reducing the number of physical components needed to protect against noise. Much of the current efforts in bosonic codes are on correcting only loss errors, while deferring the correction of phase errors -- perhaps actively suppressed -- to subsequent layers of encoding with standard qubit codes. Rotationally symmetric bosonic codes, which include the well-known cat and binomial codes, are capable of simultaneous correction of both loss and phase errors, offer an alternate route that deals with arbitrary errors already at the base layer. Grimsmo et al. [PRX 10, 011058 (2020)] analyzed the family of such codes and proposed general error-correction circuits to correct both loss and phase errors, reporting high noise thresholds in the presence of loss and phase errors on the input, while the error-correction circuits remain noiseless. A proper assessment, however, requires consideration of circuit-level noise, where the individual circuit components can themselves be faulty and introduce errors on the encoded information. Here, we carry out such a circuit-level analysis, and assess the performance of the error-correction circuits for the storage of information encoded with cat codes. While the circuits of Grimsmo et al.~are formally fault tolerant even under circuit-level noise, the thresholds are significantly worse. We show how, through waiting-time optimization and the use of squeezing, we can restore the noise requirements to ones plausibly achievable with near-term quantum hardware. Our circuit-level analysis also reveals important features of the error-correction circuits not visible in the earlier ideal-circuit perspective.

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