Phase measurement beyond the standard quantum limit using a quantum neuromorphic platform
Phase measurement constitutes a key task in many fields of science, both in the classical and quantum regime. The higher precision of such measurement offers significant advances, and can also be utilised to achieve finer estimates for quantities such as distance, the gravitational constant, ele...
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sg-ntu-dr.10356-1686842023-06-19T15:34:43Z Phase measurement beyond the standard quantum limit using a quantum neuromorphic platform Krisnanda, Tanjung Ghosh, Sanjib Paterek, Tomasz Laskowski, Wiesław Liew, Timothy Chi Hin School of Physical and Mathematical Sciences Science::Physics Electromagnetic Fields Quantum Entanglement Phase measurement constitutes a key task in many fields of science, both in the classical and quantum regime. The higher precision of such measurement offers significant advances, and can also be utilised to achieve finer estimates for quantities such as distance, the gravitational constant, electromagnetic field amplitude, etc. Here we theoretically model the use of a quantum network, composed of a randomly coupled set of two-level systems, as a processing device for phase measurement. An incoming resource state carrying the phase information interacts with the quantum network, whose emission is trained to produce a desired output signal. We demonstrate phase precision scaling following the standard quantum limit, the Heisenberg limit, and beyond. This can be achieved using quantum resource states such as NOON states or other entangled states, however, we also find that classically correlated mixtures of states are alone sufficient, provided that they exhibit quantum coherence. Our proposed setup does not require conditional measurements, and is compatible with many different types of coupling between the quantum network and the phase encoding state, hence making it attractive to a wide range of possible physical implementations. Ministry of Education (MOE) Published version T.K., S.G., and T.C.H.L. acknowledge the support by the Singapore Ministry of Education under its AcRF Tier 2 Grant MOE2019-T2-1-004. T.P. is supported by the Polish National Agency for Academic Exchange NAWA Project No. PPN/PPO/2018/1/00007/U/00001. W.L. acknowledges support from the Foundation for Polish Science (IRAP project ICTQT, Contract No. 2018/MAB/5, co-financed by EU via Smart Growth Operational Programme). 2023-06-14T08:06:15Z 2023-06-14T08:06:15Z 2022 Journal Article Krisnanda, T., Ghosh, S., Paterek, T., Laskowski, W. & Liew, T. C. H. (2022). Phase measurement beyond the standard quantum limit using a quantum neuromorphic platform. Physical Review Applied, 18(3), 034011-. https://dx.doi.org/10.1103/PhysRevApplied.18.034011 2331-7019 https://hdl.handle.net/10356/168684 10.1103/PhysRevApplied.18.034011 3 18 034011 en MOE2019-T2-1-004 Physical Review Applied © 2022 American Physical Society. All rights reserved. This paper was published in Physical Review Applied and is made available with permission of American Physical Society. application/pdf |
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Science::Physics Electromagnetic Fields Quantum Entanglement |
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Science::Physics Electromagnetic Fields Quantum Entanglement Krisnanda, Tanjung Ghosh, Sanjib Paterek, Tomasz Laskowski, Wiesław Liew, Timothy Chi Hin Phase measurement beyond the standard quantum limit using a quantum neuromorphic platform |
| description |
Phase measurement constitutes a key task in many fields of science, both in
the classical and quantum regime. The higher precision of such measurement
offers significant advances, and can also be utilised to achieve finer
estimates for quantities such as distance, the gravitational constant,
electromagnetic field amplitude, etc. Here we theoretically model the use of a
quantum network, composed of a randomly coupled set of two-level systems, as a
processing device for phase measurement. An incoming resource state carrying
the phase information interacts with the quantum network, whose emission is
trained to produce a desired output signal. We demonstrate phase precision
scaling following the standard quantum limit, the Heisenberg limit, and beyond.
This can be achieved using quantum resource states such as NOON states or other
entangled states, however, we also find that classically correlated mixtures of
states are alone sufficient, provided that they exhibit quantum coherence. Our
proposed setup does not require conditional measurements, and is compatible
with many different types of coupling between the quantum network and the phase
encoding state, hence making it attractive to a wide range of possible physical
implementations. |
| author2 |
School of Physical and Mathematical Sciences |
| author_facet |
School of Physical and Mathematical Sciences Krisnanda, Tanjung Ghosh, Sanjib Paterek, Tomasz Laskowski, Wiesław Liew, Timothy Chi Hin |
| format |
Article |
| author |
Krisnanda, Tanjung Ghosh, Sanjib Paterek, Tomasz Laskowski, Wiesław Liew, Timothy Chi Hin |
| author_sort |
Krisnanda, Tanjung |
| title |
Phase measurement beyond the standard quantum limit using a quantum neuromorphic platform |
| title_short |
Phase measurement beyond the standard quantum limit using a quantum neuromorphic platform |
| title_full |
Phase measurement beyond the standard quantum limit using a quantum neuromorphic platform |
| title_fullStr |
Phase measurement beyond the standard quantum limit using a quantum neuromorphic platform |
| title_full_unstemmed |
Phase measurement beyond the standard quantum limit using a quantum neuromorphic platform |
| title_sort |
phase measurement beyond the standard quantum limit using a quantum neuromorphic platform |
| publishDate |
2023 |
| url |
https://hdl.handle.net/10356/168684 |
| _version_ |
1772826687346573312 |