Infinite-fold Quantum Advantage in Classical Correlation Sensing
- URL: http://arxiv.org/abs/2503.17235v1
- Date: Fri, 21 Mar 2025 15:36:51 GMT
- Title: Infinite-fold Quantum Advantage in Classical Correlation Sensing
- Authors: Janis Nötzel, Pere Munar-Vallespir,
- Abstract summary: We find that when the average received energy per detector goes to zero, the ratio of the error exponents goes to infinity, indicating an infinite-fold quantum advantage.
- Score: 1.534667887016089
- License: http://creativecommons.org/licenses/by/4.0/
- Abstract: We study the hypothesis testing problem of detecting the presence of a thermal source emitting coherent quantum states towards an arbitrary but fixed number $K$ of detectors versus the situation where the detectors are presented uncorrelated thermal noise of the same average energy in the setting of asymmetric hypothesis testing. We compare two variations of this theme: In the first one the detectors perform heterodyne or homodyne detection and then transmit their measured results to a central processing unit with unlimited computational resources. In the second one the detectors are able to teleport the quantum states to the central unit, which acts on the received quantum states with unlimited quantum computational resources. We find that when the average received energy per detector goes to zero, the ratio of the error exponents goes to infinity, indicating an infinite-fold quantum advantage.
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