Technology research of 1km quantum lidar system

Bi, Siwen; Sheng, Zhe; Zhou, Zhiying; Zhang, Shoukai; Yao, Jinjin; Deng, Kaiyuan

doi:10.1117/12.2676630

Cited by 2 publications

(2 citation statements)

References 16 publications

(12 reference statements)

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“…The squeezed state light source developed in the project is an orthogonal amplitude squeezed optical field [134][135][136]. In the experiment the degree of squeezing in the quantum light field achieved was 5.6dB [134]. The proportion of optical noise to total noise was 73%.…”

Section: Sub Shot Noise Based Quantum Imaging (Ssnqi)mentioning

confidence: 97%

“…This can be used to reduce the variance in amplitude or intensity measurements, and thus enable precision better than that possible with coherent states [44]. The squeezed state light source developed in the project is an orthogonal amplitude squeezed optical field [134][135][136]. In the experiment the degree of squeezing in the quantum light field achieved was 5.6dB [134].…”

Section: Sub Shot Noise Based Quantum Imaging (Ssnqi)mentioning

confidence: 99%

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Quantum Correlation Enhanced Optical Imaging

Vernekar,

Xavier

2024

Preprint

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Quantum correlations, especially time correlations, are crucial in ghost imaging in order to significantly reduce the background noise on the one hand while increasing the imaging resolution. Moreover, the time correlations serve as a critical reference, distinguishing between signal and noise, which in turn enable clear visualization of biological samples. Quantum imaging also addresses the challenge involved in imaging delicate biological structures with minimal photon exposure and sample damage. Here we explore the recent progress in quantum correlation-based imaging, notably its impact on secure imaging and remote sensing protocols as well as on biological imaging. We also exploit the quantum characteristics of heralded single-photon sources (HSPS) combined with decoy-state methods for secure imaging. This method uses Quantum Key Distribution (QKD) principles to reduce measurement uncertainties and protect data integrity. It is highly effective in low-photon-number regimes for producing high-quality, noise-reduced images. The versatility of decoy-state methods with WCSs (WCS) is also discussed, highlighting their suitability for scenarios requiring higher photon numbers. We emphasize the dual advantages of these techniques: improving image quality through noise reduction and enhancing data security with quantum encryption, suggesting significant potential for quantum imaging in various applications, from delicate biological imaging to secure quantum communication.

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Section: Sub Shot Noise Based Quantum Imaging (Ssnqi)mentioning

confidence: 97%

Section: Sub Shot Noise Based Quantum Imaging (Ssnqi)mentioning

confidence: 99%

Quantum Correlation Enhanced Optical Imaging

Vernekar,

Xavier

2024

Preprint

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Research on deformation and cracks of dam surface based on quantum infrared detection imaging

Bi,

Zhang,

Long

2024

Quantum Sensing, Imaging, and Precision Metrology II

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After long-term operation and use of the dam, affected by various external and internal factors, the surface of the dam will produce deformation or even cracks, if not treated in time, it will greatly increase the safety risks of the dam operation.According to previous research, quantum infrared detection can obtain more clear weak information.We use quantum infrared detector to conduct imaging detection on the surface of the dam body. Compared with traditional detection methods, quantum infrared detection has the characteristics of high resolution, high signal-to-noise ratio and high sensitivity, which can improve the detection accuracy and obtain clearer image information.Through postprocessing of imaging information, cracks or other deformation and failure information are marked, and risk warning is issued for subsequent engineering construction treatment.

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Technology research of 1km quantum lidar system

Cited by 2 publications

References 16 publications

Quantum Correlation Enhanced Optical Imaging

Quantum Correlation Enhanced Optical Imaging

Research on deformation and cracks of dam surface based on quantum infrared detection imaging

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