Random Distillation Protocols in Long Baseline Telescopy

Yunkai Wang; Eric Chitambar

doi:10.1103/PhysRevLett.134.170801

Random Distillation Protocols in Long Baseline Telescopy

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Abstract

In quantum-enhanced astronomical imaging, multiple distant apertures work together by utilizing quantum resources distributed from a central server. Our findings suggest that preprocessing the stellar light received by all telescopes can improve imaging performance without increasing resource consumption. The preprocessing leverages weak quantum measurements and modifies random-party entanglement distillation protocols from quantum information science. Intuitively, this approach allows us to collapse the stellar light that is originally coherent between all telescopes to one pair of telescopes with probability arbitrarily close to one. The central server can then distribute entanglement solely to the pair of telescopes receiving a photon, thereby enhancing the efficiency of resource utilization. We discuss two types of resources that benefit from this preprocessing: shared entanglement and a shared reference frame.

Original language	English (US)
Article number	170801
Journal	Physical review letters
Volume	134
Issue number	17
Early online date	Apr 30 2025
DOIs	https://doi.org/10.1103/PhysRevLett.134.170801
State	Published - May 2 2025

ASJC Scopus subject areas

General Physics and Astronomy

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10.1103/PhysRevLett.134.170801

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abstract = "In quantum-enhanced astronomical imaging, multiple distant apertures work together by utilizing quantum resources distributed from a central server. Our findings suggest that preprocessing the stellar light received by all telescopes can improve imaging performance without increasing resource consumption. The preprocessing leverages weak quantum measurements and modifies random-party entanglement distillation protocols from quantum information science. Intuitively, this approach allows us to collapse the stellar light that is originally coherent between all telescopes to one pair of telescopes with probability arbitrarily close to one. The central server can then distribute entanglement solely to the pair of telescopes receiving a photon, thereby enhancing the efficiency of resource utilization. We discuss two types of resources that benefit from this preprocessing: shared entanglement and a shared reference frame.",

author = "Yunkai Wang and Eric Chitambar",

note = "We would like to thank Yujie Zhang for helpful discussion. This work was supported by the National Science Foundation Grants No. 1936321 and No. 2326803.",

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AB - In quantum-enhanced astronomical imaging, multiple distant apertures work together by utilizing quantum resources distributed from a central server. Our findings suggest that preprocessing the stellar light received by all telescopes can improve imaging performance without increasing resource consumption. The preprocessing leverages weak quantum measurements and modifies random-party entanglement distillation protocols from quantum information science. Intuitively, this approach allows us to collapse the stellar light that is originally coherent between all telescopes to one pair of telescopes with probability arbitrarily close to one. The central server can then distribute entanglement solely to the pair of telescopes receiving a photon, thereby enhancing the efficiency of resource utilization. We discuss two types of resources that benefit from this preprocessing: shared entanglement and a shared reference frame.

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Random Distillation Protocols in Long Baseline Telescopy

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