Classical benchmarking for microwave quantum illumination

Classical benchmarking for microwave quantum illumination

Abstract Quantum illumination theoretically promises up to a 6 dB error‐exponent advantage in target detection over the best classical protocol. The advantage is maximised by a regime that includes a very high background, which occurs naturally when one considers microwave operation. Such a regime h...

Bibliografiset tiedot
Päätekijät:	Athena Karsa, Stefano Pirandola
Aineistotyyppi:	Artikkeli
Kieli:	English
Julkaistu:	Wiley 2021-12-01
Sarja:	IET Quantum Communication
Aiheet:	entropy homodyne detection object detection optical transmitters quantum entanglement signal detection
Linkit:	https://doi.org/10.1049/qtc2.12025

Samankaltaisia teoksia

Pulsed homodyne Gaussian quantum tomography with low detection efficiency
Tekijä: M Esposito, et al.
Julkaistu: (2014-01-01)

Witnessing single-photon entanglement with local homodyne measurements: analytical bounds and robustness to losses
Tekijä: Melvyn Ho, et al.
Julkaistu: (2014-01-01)

Estimating Non-Gaussianity of a Quantum State by Measuring Orthogonal Quadratures
Tekijä: Jiyong Park
Julkaistu: (2022-02-01)

Quantum state and mode profile tomography by the overlap
Tekijä: J Tiedau, et al.
Julkaistu: (2018-01-01)

Quantum metrology with quantum Wheatstone bridge composed of Bose systems
Tekijä: Dong Xie, et al.
Julkaistu: (2023-07-01)

Increasing the Link‐distance of Free‐space Quantum Coherent Communication with Large Area Detectors
Tekijä: Rupesh Kumar, et al.
Julkaistu: (2021-03-01)

Josephson Traveling Wave Parametric Amplifiers as non-classical light source for Microwave Quantum Illumination
Tekijä: Luca Fasolo, et al.
Julkaistu: (2021-12-01)

Free space continuous variable Quantum Key Distribution with discrete phases
Tekijä: Anju Rani, et al.
Julkaistu: (2023-12-01)

Metrological detection of entanglement generated by non-Gaussian operations
Tekijä: David Barral, et al.
Julkaistu: (2024-01-01)

Detection of Interference Phase by Digital Computation of Quadrature Signals in Homodyne Laser Interferometry
Tekijä: Ondrej Cip, et al.
Julkaistu: (2012-10-01)

Continuous Variable Entanglement in Non-Zero Orbital Angular Momentum States
Tekijä: Adriana Pecoraro, et al.
Julkaistu: (2019-10-01)

Quantum Langevin equations for optomechanical systems
Tekijä: Alberto Barchielli, et al.
Julkaistu: (2015-01-01)

Heisenberg scaling precision in multi-mode distributed quantum metrology
Tekijä: Giovanni Gramegna, et al.
Julkaistu: (2021-01-01)

Single-Port Homodyne Detection in a Squeezed-State Interferometry with Optimal Data Processing
Tekijä: Likun Zhou, et al.
Julkaistu: (2021-07-01)

Proximity-Based Optical Camera Communication with Multiple Transmitters Using Deep Learning
Tekijä: Muhammad Rangga Aziz Nasution, et al.
Julkaistu: (2024-01-01)

Robust self-testing of multiparticle entanglement
Tekijä: Wu, Dian, et al.
Julkaistu: (2022)

Preparational Uncertainty Relations for N Continuous Variables
Tekijä: Spiros Kechrimparis, et al.
Julkaistu: (2016-07-01)

On Entanglement-Assisted Multistatic Radar Techniques
Tekijä: Ivan B. Djordjevic
Julkaistu: (2022-07-01)

Entanglement-Assisted Joint Monostatic-Bistatic Radars
Tekijä: Ivan B. Djordjevic
Julkaistu: (2022-05-01)

Development of an Optical System for Non-Contact Type Measurement of Heart Rate and Heart Rate Variability
Tekijä: Jyoti Gondane, et al.
Julkaistu: (2021-07-01)

Development of a High-Resolution All-Fiber Homodyne Laser Doppler Vibrometer
Tekijä: Jianhua Shang, et al.
Julkaistu: (2020-10-01)

Tilt Measurement at the Quantum Cramer–Rao Bound Using a Higher-Order Hermite–Gaussian Mode
Tekijä: Zhi Li, et al.
Julkaistu: (2023-05-01)

A Novel Approach Based on Quantum Key Distribution Using BB84 and E91 Protocol for Resilient Encryption and Eavesdropper Detection
Tekijä: Noor Ul Ain, et al.
Julkaistu: (2025-01-01)

Self-Homodyne Detection in Optical Communication Systems
Tekijä: Benjamin J. Puttnam, et al.
Julkaistu: (2014-05-01)

Experimental Certification of Quantum Entanglement Based on the Classical Complementary Correlations of Two-Qubit States
Tekijä: Zhi-Hao Bian, et al.
Julkaistu: (2021-11-01)

Fault-Tolerant One-Way Noiseless Amplification for Microwave Bosonic Quantum Information Processing
Tekijä: Hany Khalifa, et al.
Julkaistu: (2024-01-01)

Advanced optical receiver architectures for ultra-high capacity but low-cost short-reach optical interconnects
Tekijä: Honglin JI, et al.
Julkaistu: (2022-07-01)

Advanced optical receiver architectures for ultra-high capacity but low-cost short-reach optical interconnects
Tekijä: Honglin JI, et al.
Julkaistu: (2022-07-01)

Wehrl entropy and entanglement complexity of quantum spin systems
Tekijä: Chen Xu, et al.
Julkaistu: (2025-01-01)

A Compensation Method for Nonlinearity Errors in Optical Interferometry
Tekijä: Yanlu Li, et al.
Julkaistu: (2023-09-01)

Comment on ‘Single particle nonlocality with completely independent reference states’
Tekijä: Tamoghna Das, et al.
Julkaistu: (2022-01-01)

Study of Self-Homodyne Coherent System Using Multicore Fiber for Data Center Links
Tekijä: Xiaojun Liang, et al.
Julkaistu: (2022-01-01)

Quantum illumination radars: Target detection
Tekijä: Jingxin Wang, et al.
Julkaistu: (2024-09-01)

Testing the postulates of quantum mechanics with coherent states of light and homodyne detection
Tekijä: Lorcán O Conlon, et al.
Julkaistu: (2024-01-01)

Quantum coherence and the bell inequality violation: a numerical experiment with the cavity QEDs
Tekijä: Suirong He, et al.
Julkaistu: (2025-02-01)

Experimental Detection of Initial System–Environment Entanglement in Open Systems
Tekijä: Gaoyan Zhu, et al.
Julkaistu: (2022-11-01)

Deterministic Quantum Secure Direct Communication Protocol Based on Hyper-Entangled State
Tekijä: Jian Li, et al.
Julkaistu: (2019-01-01)

Characterization of a Quantum Random Number Generator Based on Vacuum Fluctuations
Tekijä: Maurício J. Ferreira, et al.
Julkaistu: (2021-08-01)

The physical origin of a photon-number parity effect in cavity quantum electrodynamics
Tekijä: Agostino Migliore, et al.
Julkaistu: (2021-11-01)

A Quantum Detectable Byzantine Agreement Protocol Using Only EPR Pairs
Tekijä: Theodore Andronikos, et al.
Julkaistu: (2023-07-01)