Explicit error-correction scheme and code distance for bosonic codes with rotational symmetry

• URL: http://arxiv.org/abs/2311.13670v2
• Date: Wed, 13 Mar 2024 15:49:24 GMT
• Title: Explicit error-correction scheme and code distance for bosonic codes with rotational symmetry
• Authors: Benjamin Marinoff, Miles Bush, Joshua Combes
• Abstract summary: We show that codes with rotation symmetry have a distance of $(d_n, d_theta)=(N, pi/N)$ with respect to number and rotation errors. We also prove that codes with an $N$-fold rotation symmetry have a distance of $(d_n, d_theta)=(N, pi/N)$ with respect to number and rotation errors.
• Score: 0.0
• License: http://creativecommons.org/licenses/by/4.0/
• Abstract: Bosonic codes with rotational symmetry are currently one of the best performing quantum error correcting codes. Little is known about error propagation and code distance for these rotation codes in contrast with qubit codes and Bosonic codes with translation symmetry. We use a general purpose error basis that is naturally suited to codes with rotation symmetry to compute how errors propagate through gates. This error basis allows us to give an explicit error detection, decoding, and correction scheme for any code with rotation symmetry. We also prove that codes with an $N$-fold rotation symmetry have a distance of $(d_n, d_\theta)=(N, \pi/N)$ with respect to number and rotation errors.

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