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Abstract
We propose a quantum-enhanced lidar system to estimate a target’s radial velocity, which employs squeezed and frequency-entangled signal and idler beams. We compare its performance against a classical protocol using a coherent state with the same pulse duration and energy, showing that quantum resources provide a precision enhancement in the estimation of the velocity of the object. We identify three distinct parameter regimes characterized by the amount of squeezing and frequency entanglement. In two of them, a quantum advantage exceeding the standard quantum limit is achieved assuming no photon losses. Additionally, we show that an optimal measurement to attain these results in the lossless case is frequency-resolved photon counting. Finally, we consider the effect of photon losses for the high-squeezing regime, which leads to a constant factor quantum advantage higher than 3 dB in the variance of the estimator, given a roundtrip lidar-to-target-to-lidar transmissivity larger than 50%.
Original language | English |
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Article number | 147 |
Number of pages | 9 |
Journal | npj Quantum Information |
Volume | 8 |
Issue number | 1 |
DOIs | |
Publication status | Published - Dec 2022 |
MoE publication type | A1 Journal article-refereed |
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QuantumMicrowave_research: Quantum communication and sensing with low-powered devices in the microwave regime
Di Candia, R. (Principal investigator) & Alushi, U. (Project Member)
01/09/2022 → 31/12/2025
Project: Academy of Finland: Other research funding
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QuantumMicrowave: Quantum communication and sensing with low-powered devices in the microwave regime
Di Candia, R. (Principal investigator)
01/09/2022 → 31/08/2027
Project: Academy of Finland: Other research funding
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Green-MIQUEC: Low-powered microwave quantum-enhanced communication: conceptualisation and preliminary design
Di Candia, R. (Principal investigator)
27/02/2020 → 28/02/2022
Project: EU: MC