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Bibliographic Details
Main Authors: Ward, William, Hariri, Abdulkarim, Zhang, Zheshen
Format: Preprint
Published: 2024
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Online Access:https://arxiv.org/abs/2410.07544
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author Ward, William
Hariri, Abdulkarim
Zhang, Zheshen
author_facet Ward, William
Hariri, Abdulkarim
Zhang, Zheshen
contents Quantum illumination (QI) provides entanglement-enabled target-detection enhancement, despite operating in an entanglement-breaking environment. Existing experimental studies of QI have utilized a Bayesian approach, assuming that the target is equally likely to be present or absent before detection, to demonstrate an advantage over classical target detection. However, such a premise breaks down in practical operational scenarios in which the prior probability is unknown, thereby hindering QI's applicability to real-world target-detection scenarios. In this work, we adopt the Neyman-Pearson criterion in lieu of the error probability for equally likely target absence or presence as our figure of merit for QI. We demonstrate an unconditional quantum advantage over the optimal classical-illumination protocol as benchmarked by the receiver operating characteristic, which examines detection probability versus false-alarm probability without resorting to known prior probabilities. Our work represents a critical advancement in adapting quantum-enhanced sensing to practical operational settings.
format Preprint
id arxiv_https___arxiv_org_abs_2410_07544
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Entanglement-Enhanced Neyman-Pearson Target Detection
Ward, William
Hariri, Abdulkarim
Zhang, Zheshen
Quantum Physics
Quantum illumination (QI) provides entanglement-enabled target-detection enhancement, despite operating in an entanglement-breaking environment. Existing experimental studies of QI have utilized a Bayesian approach, assuming that the target is equally likely to be present or absent before detection, to demonstrate an advantage over classical target detection. However, such a premise breaks down in practical operational scenarios in which the prior probability is unknown, thereby hindering QI's applicability to real-world target-detection scenarios. In this work, we adopt the Neyman-Pearson criterion in lieu of the error probability for equally likely target absence or presence as our figure of merit for QI. We demonstrate an unconditional quantum advantage over the optimal classical-illumination protocol as benchmarked by the receiver operating characteristic, which examines detection probability versus false-alarm probability without resorting to known prior probabilities. Our work represents a critical advancement in adapting quantum-enhanced sensing to practical operational settings.
title Entanglement-Enhanced Neyman-Pearson Target Detection
topic Quantum Physics
url https://arxiv.org/abs/2410.07544