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Main Authors: Renault, Paul, Yard, Patrick, Pooser, Raphael, Zaidi, Hussain
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2511.14737
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author Renault, Paul
Yard, Patrick
Pooser, Raphael
Zaidi, Hussain
author_facet Renault, Paul
Yard, Patrick
Pooser, Raphael
Zaidi, Hussain
contents We present an architecture for the generation of GKP states in which quadrature squeezing operations are used to control the average photon number statistics of probabilistic photon number measurements on Gaussian resource states. Specifically, we present an architecture employing a teleportation-based squeezing protocol and polynomial-gate applications integrated into a time-multiplexed multi-mode cluster state to generate cat states with high amplitudes, which are consequently used to generate GKP states with high quadrature effective squeezing. Compared to our previous work, in addition to using squeezing as a resource, the present architecture reduces damping and noise by minimizing the number of homodyne measurements required in GKP state generation. We demonstrate the effectiveness of these improvements - including dynamic input-state resetting and an improved breeding algorithm - by achieving a fault-tolerance threshold of 11.5 dB cluster squeezing using the RHG surface code for error correction, without requiring active switching or photon-number resource states.
format Preprint
id arxiv_https___arxiv_org_abs_2511_14737
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Squeezing-Enhanced Photon-Number Measurements for GKP State Generation
Renault, Paul
Yard, Patrick
Pooser, Raphael
Zaidi, Hussain
Quantum Physics
We present an architecture for the generation of GKP states in which quadrature squeezing operations are used to control the average photon number statistics of probabilistic photon number measurements on Gaussian resource states. Specifically, we present an architecture employing a teleportation-based squeezing protocol and polynomial-gate applications integrated into a time-multiplexed multi-mode cluster state to generate cat states with high amplitudes, which are consequently used to generate GKP states with high quadrature effective squeezing. Compared to our previous work, in addition to using squeezing as a resource, the present architecture reduces damping and noise by minimizing the number of homodyne measurements required in GKP state generation. We demonstrate the effectiveness of these improvements - including dynamic input-state resetting and an improved breeding algorithm - by achieving a fault-tolerance threshold of 11.5 dB cluster squeezing using the RHG surface code for error correction, without requiring active switching or photon-number resource states.
title Squeezing-Enhanced Photon-Number Measurements for GKP State Generation
topic Quantum Physics
url https://arxiv.org/abs/2511.14737