Quantum-enhanced noise radar

Chang, Christophe; Vadiraj, A. M.; Bourassa, Jérôme; Balaji, Bhashyam; Wilson, Christopher

doi:10.1063/1.5085002

Cited by 152 publications

(172 citation statements)

References 21 publications

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“…The protocol has also been proposed to be useful for detecting the presence of a target object embedded within a noisy background, despite environmental perturbations and losses destroying the initial entanglement [5,6,7].In 2013, Lopaeva et al performed an experimental demonstration of the quantum illumination principle, to determine the presence or absence of a semi-transparent object, by exploiting intensity correlations of a quantum origin in the presence of thermal light [8]. Additionally, a quantum illumination protocol has been experimentally demonstrated in the microwave domain [9] and a further demonstration in which joint detection of the signal and idler is not required [10]. However, these previous demonstrations were restricted 1 to simply detecting the presence or absence of a target, rather than performing any form of spatially resolved imaging.…”

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confidence: 99%

Imaging through noise with quantum illumination

et al. 2020

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The contrast of an image can be degraded by the presence of background light and sensor noise.To overcome this degradation, quantum illumination protocols have been theorised (Science 321 (2008), Physics Review Letters 101 (2008)) that exploit the spatial correlations between photonpairs. Here we demonstrate the first full-field imaging system using quantum illumination, by an enhanced detection protocol. With our current technology we achieve a rejection of background and stray light of order 5 and also report an image contrast improvement up to a factor of 5.5, which is resilient to both environmental noise and transmission losses. The quantum illumination protocol differs from usual quantum schemes in that the advantage is maintained even in the presence of noise and loss. Our approach may enable laboratory-based quantum imaging to be applied to real-world applications where the suppression of background light and noise is important, such as imaging under low-photon flux and quantum LIDAR.Conventional illumination uses a spatially and temporally random sequence of photons to illuminate an object, whereas quantum illumination can use spatial correlations between pairs of photons to achieve performance enhancements in the presence of noise and/or losses. This enhancement is made possible by using detection techniques that preferentially select photon-pair events over isolated background events.The quantum illumination protocol was introduced by Lloyd [1], and generalized to Gaussian states by Tan et al. [2], where they proposed a practical version of the protocol. Quantum illumination has applications in the context of quantum information protocol such as secure communication [3,4] where it secures communication against passive eavesdropping techniques that take advantage of noise and losses. The protocol has also been proposed to be useful for detecting the presence of a target object embedded within a noisy background, despite environmental perturbations and losses destroying the initial entanglement [5,6,7].In 2013, Lopaeva et al. performed an experimental demonstration of the quantum illumination principle, to determine the presence or absence of a semi-transparent object, by exploiting intensity correlations of a quantum origin in the presence of thermal light [8]. Additionally, a quantum illumination protocol has been experimentally demonstrated in the microwave domain [9] and a further demonstration in which joint detection of the signal and idler is not required [10]. However, these previous demonstrations were restricted 1 to simply detecting the presence or absence of a target, rather than performing any form of spatially resolved imaging. The acquisition of an image using quantum illumination has recently been reported [11], but that demonstration was performed using a mono-mode source of correlations and by raster-scanning the object within this single-mode beam. The aforementioned demonstration may be seen as a qualitative assessment of the method but a full field imaging implementation of the qua...

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confidence: 99%

Imaging through noise with quantum illumination

et al. 2020

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“…Quantum illumination radars [1]- [4], which are based on a phenomenon called entanglement, are a particularly well-studied class of quantum radars. An experimental implementation of a quantum two-mode squeezing (QTMS) radar, a variant of quantum illumination radar, was recently demonstrated [5]- [7]. Although it is not a full quantum radar (it uses amplifiers which break the entanglement), it demonstrates all the necessary ingredients of an entanglement-based radar, including the generation of an entangled signal and the transmission of microwaves through free space.…”

Section: Introductionmentioning

confidence: 99%

“…[8]) in that they rely on the correlation between two noise signals for target detection. In fact, the name adopted for QTMS radar in [5] was quantum-enhanced noise radar. One of the noise signals is transmitted toward a target, while the other is retained within the radar system.…”

Section: Introductionmentioning

confidence: 99%

Quantum Two-Mode Squeezing Radar and Noise Radar: Correlation Coefficients for Target Detection

2020

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Quantum two-mode squeezing (QTMS) radars and noise radars detect targets by correlating the received signal with an internally stored recording. A covariance matrix can be calculated between the two which, in theory, is a function of a single correlation coefficient. This coefficient can be used to decide whether a target is present or absent. We can estimate the correlation coefficient by minimizing the Frobenius norm between the sample covariance matrix and the theoretically expected form of the matrix. Using simulated data, we show that the estimates follow a Rice distribution whose parameters are simple functions of the underlying, "true" correlation coefficient as well as the number of integrated samples. We obtain an explicit expression for the receiver operating characteristic curve that results when the correlation coefficient is used for target detection. This is an important first step toward performance prediction for QTMS radars.

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“…The properties of quantum states have disclosed the possibility of realizing this task beyond classical limits [1][2][3]. One of the major applications to enhance the ability of target recognition is quantum illumination [4][5][6][7][8][9], which is the most known protocol for bosonic quantum sensing [10]. Quantum illumination provides us with a potential platform to detect the low-reflectivity object embedded in a bright environment, and it is more efficiently than the way by using classical resources [5,11,12].…”

Section: Introductionmentioning

confidence: 99%

Quantum illumination assistant with error-correcting codes

Zhang

Chen

et al. 2020

New J. Phys.

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We scheme how to enhance the detection ability of quantum target recognition without using entanglement resources. Based on the commonly used error-correcting codes and corresponding decoding method, our scheme gives lower error probability and higher signal-to-noise ratio (SNR) in comparison with the conventional entanglement protocols. In addition, we further investigate the interplay between the SNR and the detection efficiency in quantum target recognition. Results show that, they behave a completely reverse trend when increasing the auxiliary dimension. This is an important limiting factor when optimizing the detection process. Under the existing experimental conditions, our protocol has stronger ability to resist environmental noise when keeping a certain SNR and detection efficiency. Our scheme provides a potential platform for further research and implementation of quantum target recognition.

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Quantum-enhanced noise radar

Cited by 152 publications

References 21 publications

Imaging through noise with quantum illumination

Imaging through noise with quantum illumination

Quantum Two-Mode Squeezing Radar and Noise Radar: Correlation Coefficients for Target Detection

Quantum illumination assistant with error-correcting codes

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