Realistic model of entanglement-enhanced sensing in optical fibers

Krueper, Gregory; Yu, Charles; Libby, Stephen B.; Mellors, R. J.; Cohen, Lior; Gopinath, Juliet T.

doi:10.1364/oe.451058

Opt. Express

2022

DOI: 10.1364/oe.451058

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Realistic model of entanglement-enhanced sensing in optical fibers

Gregory Krueper

Charles Yu

Stephen B. Libby

et al.

Abstract: Experimental limitations such as optical loss and noise have prevented entanglement-enhanced measurements from demonstrating a significant quantum advantage in sensitivity. Holland-Burnett entangled states can mitigate these limitations and still present a quantum advantage in sensitivity. Here we model a fiber-based Mach-Zehnder interferometer with internal loss, detector efficiency, and external phase noise and without pure entanglement. This model features a practical fiber source that transforms the two-mo… Show more

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2024

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Federated quantum long short-term memory (FedQLSTM)

Chehimi,

Chen,

Saad

et al. 2024

Quantum Mach. Intell.

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Quantum federated learning (QFL) can facilitate collaborative learning across multiple clients using quantum machine learning (QML) models, while preserving data privacy. Although recent advances in QFL span different tasks like classification while leveraging several data types, no prior work has focused on developing a QFL framework that utilizes temporal data to approximate functions useful to analyze the performance of distributed quantum sensing networks. In this paper, a novel QFL framework that is the first to integrate quantum long short-term memory (QLSTM) models with temporal data is proposed. The proposed federated QLSTM (FedQLSTM) framework is exploited for performing the task of function approximation. In this regard, three key use cases are presented: Bessel function approximation, sinusoidal delayed quantum feedback control function approximation, and Struve function approximation. Simulation results confirm that, for all considered use cases, the proposed FedQLSTM framework achieves a faster convergence rate under one local training epoch, minimizing the overall computations, and saving 25–33% of the number of communication rounds needed until convergence compared to an FL framework with classical LSTM models.

show abstract

Federated quantum long short-term memory (FedQLSTM)

Chehimi,

Chen,

Saad

et al. 2024

Quantum Mach. Intell.

View full text Add to dashboard Cite

show abstract

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Realistic model of entanglement-enhanced sensing in optical fibers

Cited by 1 publication

References 49 publications

Federated quantum long short-term memory (FedQLSTM)

Federated quantum long short-term memory (FedQLSTM)

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