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Ultimate Accuracy Limit of Quantum Pulse-Compression Ranging

Quntao Zhuang, Jeffrey H. Shapiro

2022Physical Review Letters53 citationsDOIOpen Access PDF

Abstract

Radars use time-of-flight measurement to infer the range to a distant target from its return's round-trip range delay. They typically transmit a high time-bandwidth product waveform and use pulse-compression reception to simultaneously achieve satisfactory range resolution and range accuracy under a peak transmitted-power constraint. Despite the many proposals for quantum radar, none have delineated the ultimate quantum limit on ranging accuracy. We derive that limit through continuous-time quantum analysis and show that quantum illumination ranging-a quantum pulse-compression radar that exploits the entanglement between a high time-bandwidth product transmitted signal pulse and and a high time-bandwidth product retained idler pulse-achieves that limit. We also show that quantum illumination ranging offers mean-squared range-delay accuracy that can be tens of dB better than that of a classical pulse-compression radar of the same pulse bandwidth and transmitted energy.

Topics & Concepts

RangingPhysicsQuantum sensorQuantum entanglementQuantumRadarLimit (mathematics)Quantum limitWaveformRange (aeronautics)Quantum metrologyBandwidth (computing)Pulse (music)Product (mathematics)Quantum imagingResolution (logic)Heisenberg limitSIGNAL (programming language)Quantum channelQuantum mechanicsQuantum opticsPulse compressionQuantum stateQuantum technologyOpticsQuantum informationObserver (physics)PhotonicsQuantum Information and CryptographyNon-Invasive Vital Sign MonitoringAdvanced Optical Sensing Technologies
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