Purity in the QTMS radar

Hosseiny, Seyed Mohammad; Norouzi, Milad; Seyed-Yazdi, Jamileh; Irannezhad, Fatemeh

doi:10.1088/1402-4896/accc5b

Cited by 3 publications

(2 citation statements)

References 60 publications

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“…In addition, in [65], the entanglement between signal and idler by logarithmic negativity tool has been discussed completely, and various factors affecting the QTMS radar performance have been investigated. Moreover, in [66], the decoherence effects in QTMS radar have been addressed and from another aspect, the performance of quantum radar was improved. In this paper, the main focus is on the difference in the performance of the DJPA and NDJPA in the QTMS radar simulation to target detection, which is discussed follow.…”

Section: Post-processingmentioning

confidence: 99%

Observation of the performance enhancement of a non-degenerate JPA versus degenerate JPA in a QTMS radar simulation

Norouzi,

Hosseiny,

Seyed-Yazdi

et al. 2024

Eng. Res. Express

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Small differences in the types of Josephson parametric amplifiers (JPAs) can cause significant changes in quantum two-mode squeezed (QTMS) radars. In this work, taking into account these differences, we examine two types of JPA in terms of pumping in the quantum radar, including degenerate JPA (DJPA) and non-degenerate JPA (NDJPA) under the same conditions, leading to results very significant for the design of a QTMS radar. This study shows that QTMS radar performance is better than that of the DJPA scenario when using the NDJPA scenario. In addition, we calculated the signal-to-noise (SNR) ratio and receiver operating characteristic (ROC) for two scenarios, both of which show the superiority of the NDJPA scenario. The SNR of the QTMS radar in the NDJPA case is about 1.7 dB higher than in the DJPA case. In addition, the channel number of detection probability in the NDJPA scenario is lower than that in the DJPA scenario, which indicates better ROC performance. Finally, using an NDJPA in a quantum radar can achieve a performance improvement over a quantum radar using a DJPA.

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Section: Post-processingmentioning

confidence: 99%

Observation of the performance enhancement of a non-degenerate JPA versus degenerate JPA in a QTMS radar simulation

Norouzi,

Hosseiny,

Seyed-Yazdi

et al. 2024

Eng. Res. Express

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“…Moreover, the same results are obtained for different Ns N when comparing the two cases. In recent articles [46,47], important factors in improving the performance of the QTMS radar have been investigated, with respect to the effects of decoherence and entanglement, respectively. Here, the effects of the bandwidth and quantum correlation changes on the SNR are investigated.…”

Section: Snr and Rocmentioning

confidence: 99%

Investigation of the JPA-Bandwidth Improvement in the Performance of the QTMS Radar

Norouzi,

Seyed-Yazdi,

Hosseiny

et al. 2023

Entropy

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Josephson parametric amplifier (JPA) engineering is a significant component in the quantum two-mode squeezed radar (QTMS) to enhance, for instance, radar performance and the detection range or bandwidth. We simulated a proposal of using engineered JPA (EJPA) to enhance the performance of a QTMS radar. We defined the signal-to-noise ratio (SNR) and detection range equations of the QTMS radar. The engineered JPA led to a remarkable improvement in the quantum radar performance, i.e., a large enhancement in SNR of about 6 dB more than the conventional QTMS radar (with respect to the latest version of the QTMS radar and not to the classical radar), a substantial improvement in the probability of detection through far fewer channels. The important point in this work was that we expressed the importance of choosing suitable detectors for the QTMS radars. Finally, we simulated the transmission of the signal to the target in the QTMS radar and obtained a huge increase in the QTMS radar range, up to 482 m in the current study.

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