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Biased Gottesman-Kitaev-Preskill repetition code

Matthew P. Stafford, Nicolas C. Menicucci

2023Physical review. A/Physical review, A14 citationsDOIOpen Access PDF

Abstract

Continuous-variable quantum computing architectures based upon the Gottesman-Kitaev-Preskill (GKP) encoding have emerged as a promising candidate because one can achieve fault tolerance with a probabilistic supply of GKP states and Gaussian operations. Furthermore, by generalizing to rectangular-lattice GKP states, a bias can be introduced and exploited through concatenation with qubit codes that show improved performance under biasing. However, these codes (such as the XZZX surface code) still require weight-four stabilizer measurements and have complex decoding requirements to overcome. In this work, we study the code-capacity behavior of a rectangular-lattice GKP encoding concatenated with a repetition code under an isotropic Gaussian displacement channel. We find a numerical threshold of $\ensuremath{\sigma}=0.599$ for the noise's standard deviation, which outperforms the biased GKP planar surface code with a trade-off of increased biasing at the GKP level. This is all achieved with only weight-two stabilizer operators and simple decoding at the qubit level. Furthermore, with moderate levels of bias (aspect ratio $\ensuremath{\le}2.4$) and nine or fewer data modes, significant reductions in logical error rates can still be achieved for $\ensuremath{\sigma}\ensuremath{\le}0.3$, opening the possibility of using biased GKP repetition codes as a simple low-level qubit encoding for further concatenation.

Topics & Concepts

Concatenation (mathematics)Decoding methodsQubitLattice (music)GaussianAlgorithmMathematicsComputer scienceTopology (electrical circuits)PhysicsQuantumQuantum mechanicsArithmeticCombinatoricsAcousticsQuantum Computing Algorithms and ArchitectureAdvanced Memory and Neural ComputingQuantum Information and Cryptography
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