Compact All-Fiber Quantum-Inspired LiDAR with > 100dB Noise Rejection
and Single Photon Sensitivity
- URL: http://arxiv.org/abs/2308.00195v2
- Date: Wed, 2 Aug 2023 01:42:07 GMT
- Title: Compact All-Fiber Quantum-Inspired LiDAR with > 100dB Noise Rejection
and Single Photon Sensitivity
- Authors: Han Liu, Changhao Qin, Georgios Papangelakis, Meng Lon Iu, Amr S Helmy
- Abstract summary: Entanglement and correlation of quantum light can enhance LiDAR sensitivity in the presence of strong background noise.
We develop and demonstrate a quantum-inspired LiDAR prototype based on coherent measurement of classical time-frequency correlations.
- Score: 6.07319870953345
- License: http://creativecommons.org/licenses/by/4.0/
- Abstract: Entanglement and correlation of quantum light can enhance LiDAR sensitivity
in the presence of strong background noise. However, the power of such quantum
sources is fundamentally limited to a stream of single photons and cannot
compete with the detection range of high-power classical LiDAR transmitters. To
circumvent this, we develop and demonstrate a quantum-inspired LiDAR prototype
based on coherent measurement of classical time-frequency correlations. This
system uses a high-power classical source and maintains the high noise
rejection advantage of quantum LiDARs. In particular, we show that it can
achieve over 100dB rejection (with 100ms integration time) of
indistinguishable(with statistically identical properties in every degrees of
freedom) in-band noise while still being sensitive to single photon signals. In
addition to the LiDAR demonstration, we also discuss the potential of the
proposed LiDAR receiver for quantum information applications. In particular, we
propose the chaotic quantum frequency conversion technique for coherent
manipulation of high dimensional quantum states of light. It is shown that this
technique can provide improved performance in terms of selectivity and
efficiency as compared to pulse-based quantum frequency conversion.
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