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Bosonic Continuous Variable Quantum Computing Photonic Quantum Computing Quantum Compilation Routing Architecture Quantum Error Correction Fault Tolerance

LiDMaS: Architecture-Level Modeling of Fault-Tolerant Magic-State Injection in GKP Photonic Qubits

arXiv

Authors: Dennis Delali Kwesi Wayo

Year

2026

Paper ID

3480

Status

Preprint

Abstract Read

~2 min

Abstract Words

192

Citations

N/A

Abstract

Fault-tolerant quantum computation in photonic architectures requires efficient preparation of high-fidelity logical magic states under realistic constraints of finite squeezing and photon loss. An architecture-level study of logical T-gate magic-state preparation in Gottesman--Kitaev--Preskill (GKP)-encoded photonic qubits is presented using a repeat-until-success (RUS) injection protocol combined with outer surface-code protection. A lightweight density-matrix simulator based on standard numerical linear algebra is employed, mapping finite squeezing to effective logical dephasing, incorporating logical depolarizing noise, and treating photon loss as a heralded erasure process. Parameter sweeps are performed over squeezing values from 8 to 16 dB, baseline loss probabilities between 0.01 and 0.03, and surface-code distances d=1,3,5, and 7. Across this regime, RUS success probabilities exceed 0.94, with average injection overhead between 1.15 and 1.20 rounds per successful attempt. After outer-code protection, logical fidelities reach F_log approx 0.77--0.80, exhibiting weak sensitivity to moderate photon loss but strong monotonic dependence on squeezing. Sensitivity analysis identifies finite squeezing as the dominant continuous error source, while loss primarily impacts heralded failure rates. Phase-boundary diagrams determine minimum squeezing requirements to achieve success probability ge 0.95 and logical fidelity ge 0.79 as a function of code distance, providing quantitative design guidance for scalable photonic fault-tolerant architectures.

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This paper contributes to the Quantum Error Correction & Fault Tolerance research area in the Quantum Articles archive.
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Fault-tolerant quantum computation in photonic architectures requires efficient preparation of high-fidelity logical magic states under realistic constraints of finite...

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References & Citation Signals

[1] DOI https://doi.org/arXiv:2601.16244 [2] arXiv https://arxiv.org/abs/2601.16244 [3] Publisher https://arxiv.org/abs/2601.16244

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