STQS: A Unified System Architecture for Spatial Temporal Quantum Sensing - INSPIRE

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STQS: A Unified System Architecture for Spatial Temporal Quantum Sensing

Anastashia Jebraeilli
(
- PNL, Richland
)
,
Chenxu Liu
,
Keyi Yin
(
- PNL, Richland
)
,
Erik W. Lentz
,
Yufei Ding
(
- PNL, Richland
)

Feb 24, 2025

17 pages

e-Print:

2502.17778 [quant-ph]

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Abstract: (arXiv)

Quantum sensing (QS) harnesses quantum phenomena to measure physical observables with extraordinary precision, sensitivity, and resolution. Despite significant advancements in quantum sensing, prevailing efforts have focused predominantly on refining the underlying sensor materials and hardware. Given the growing demands of increasingly complex application domains and the continued evolution of quantum sensing technologies, the present moment is the right time to systematically explore distributed quantum sensing architectures and their corresponding design space. We present STQS, a unified system architecture for spatiotemporal quantum sensing that interlaces four key quantum components: sensing, memory, communication, and computation. By employing a comprehensive gate-based framework, we systemically explore the design space of quantum sensing schemes and probe the influence of noise at each state in a sensing workflow through simulation. We introduce a novel distance-based metric that compares reference states to sensing states and assigns a confidence level. We anticipate that the distance measure will serve as an intermediate step towards more advanced quantum signal processing techniques like quantum machine learning. To our knowledge, STQS is the first system-level framework to integrate quantum sensing within a coherent, unified architectural paradigm. STQS provides seamless avenues for unique state preparation, multi-user sensing requests, and addressing practical implementations. We demonstrate the versatility of STQS through evaluations of quantum radar and qubit-based dark matter detection. To highlight the near-term feasibility of our approach, we present results obtained from IBM's Marrakesh and IonQ's Forte devices, validating key STQS components on present day quantum hardware.

Note:

17 pages, 20 figures

References(64)

Figures(5)

[1]

Gerardo Adesso and Fabrizio Illuminati.. Gaussian measures of entanglement versus negativities: Ordering of two-mode Gaussian states

- Phys.Rev.A 72 (2005) 032334
•
DOI:
- 10.1103/PhysRevA.72.032334

[2]

N. Aghanim
,
Y. Akrami
,
M. Ashdown
,
J. Aumont
,
C. Baccigalupi

et al.

[3]

Remote sensing of soil moisture using Rydberg atoms and satellite signals of opportunity

- Sci.Rep. 14 (2024) 1, 18025
•
e-Print:
- 2403.03175
•
DOI:
- 10.1038/s41598-024-68914-6

[4]

Microwave Quantum Illumination

Shabir Barzanjeh
(
- Aachen, Tech. Hochsch.
)
,
Saikat Guha
(
- BBN Advanced Computers, Cambridge
)
,
Christian Weedbrook
(
- Unlisted, CA
)
,
David Vitali
(
- Camerino U.
)
,
Jeffrey H. Shapiro
(
- MIT, LNS
)

et al.

- Phys.Rev.Lett. 114 (2015) 8, 080503
•
e-Print:
- 1503.00189
•
DOI:
- 10.1103/PhysRevLett.114.080503

[5]

An optical lattice clock with accuracy and stability at the 10-18 level

B.J. Bloom
,
T.L. Nicholson
,
J.R. Williams
,
S.L. Campbell
,
M. Bishof

et al.

- Nature 506 (2014) 7486

[6]

Measure for the Degree of Non-Markovian Behavior of Quantum Processes in Open Systems

- Phys.Rev.Lett. 103 (2009) 21, 210401
•
DOI:
- 10.1103/PhysRevLett.103.210401

[7]

Angela Sara Cacciapuoti, Jessica Illiano, and Marcello Caleffi.. Quantum Internet Addressing

- IEEE Network 38 (2024) 1
•
DOI:
- 10.1109/mnet

[8]

Quantum Enhancement in Dark Matter Detection with Quantum Computation

Shion Chen
(
- Tokyo U., ICEPP
)
,
Hajime Fukuda
(
- Tokyo U.
)
,
Toshiaki Inada
(
- Tokyo U., ICEPP
)
,
Takeo Moroi
(
- Tokyo U. and
- QUP, Tsukuba
)
,
Tatsumi Nitta
(
- Tokyo U., ICEPP
)

et al.

- Phys.Rev.Lett. 133 (2024) 2, 021801
•
e-Print:
- 2311.10413
•
DOI:
- 10.1103/PhysRevLett.133.021801

[9]

A direct empirical proof of the existence of dark matter

et al.

- Astrophys.J.Lett. 648 (2006) L109-L113
•
e-Print:
- astro-ph/0608407
•
DOI:
- 10.1086/508162

[10]

Yacine Dalichaouch

Peter V. Czipott
,
Alexander R. Perry

- Proc.SPIE Int.Soc.Opt.Eng. 129 (2001) 134
•
DOI:
- 10.1117/12.441262

[11]

Quantum sensing with tunable superconducting qubits: optimization and speed-up

- New J.Phys. 26 (2024) 10, 103029
•
e-Print:
- 2211.08344
•
DOI:
- 10.1088/1367-2630/ad49c5

[12]

Quantum sensing with superconducting circuits

S. Danilin
,
M. Weides

•
e-Print:
- 2103.11022

[13]

Dynamics of non-Markovian open quantum systems

- Rev.Mod.Phys. 89 (2017) 1, 015001
•
DOI:
- 10.1103/RevModPhys.89.015001

[14]

Quantum sensing

- Rev.Mod.Phys. 89 (2017) 3, 035002,
- Rev.Mod.Phys. 89 (2017) 035002
•
e-Print:
- 1611.02427
•
DOI:
- 10.1103/RevModPhys.89.035002

[15]

Superconducting Circuits for Quantum Information: An Outlook

Michel H. Devoret
,
Michel H. Devoret
,
Robert J. Schoelkopf

- Science 339 (2013) 1169-1174
•
- https://api.semanticscholar.org/CorpusID

[16]

Single-molecule scale magnetic resonance spectroscopy using quantum diamond sensors

- Rev.Mod.Phys. 96 (2024) 2, 025001
•
e-Print:
- 2501.03620
•
DOI:
- 10.1103/RevModPhys.96.025001

[17]

Single-mode displacement sensor

- Phys.Rev.A 95 (2017) 1, 012305
•
DOI:
- 10.1103/PhysRevA.95.012305

[18]

Rydberg Atom Electric Field Sensors for Communications and Sensing

- IEEE Trans.Quantum Eng. 2 (2021) 1-13
•
DOI:
- 10.1109/TQE.2021.3065227

[19]

The Superconducting Quasiparticle-Amplifying Transmon: A Qubit-Based Sensor for meV Scale Phonons and Single THz Photons

Caleb W. Fink
(
- Los Alamos
)
,
Chiara P. Salemi
(
- SLAC and
- KIPAC, Menlo Park
)
,
Betty A. Young
(
- Santa Clara U.
)
,
David I. Schuster
(
- Stanford U., Phys. Dept.
)
,
Noah A. Kurinsky
(
- SLAC and
- KIPAC, Menlo Park
)

- Phys.Rev.Applied 22 (2024) 054009
•
e-Print:
- 2310.01345
•
DOI:
- 10.1103/PhysRevApplied.22.054009

[20]

Quantum Metrology

Vittorio Giovannetti
(
- NEST-INFM
)
,
Seth Lloyd
(
- MIT, MKI
)
,
Lorenzo Maccone
(
- Pavia U. and
- INFN, Pavia
)

- Phys.Rev.Lett. 96 (2006) 1, 010401
•
DOI:
- 10.1103/PhysRevLett.96.010401

[21]

Encoding a qubit in an oscillator

Daniel Gottesman
(
- Microsoft, Redmond
)
,
Alexei Kitaev
(
- Microsoft, Redmond
)
,
John Preskill
(
- Caltech
)

- Phys.Rev.A 64 (2001) 012310
•
e-Print:
- quant-ph/0008040
•
DOI:
- 10.1103/PhysRevA.64.012310

[22]

Quantum lost and found

M. Gregoratti
,
R.F. Werner

- J.Mod.Opt. 50 (2003) 6-7
•
DOI:
- 10.1080/09500340308234541
•
- https://www.tandfonline.com/doi/pdf/

[22]

M. Gregoratti
,
R.F. Werner

DOI:
- 10.1080/09500340308234541

[23]

Estimation of Gaussian random displacement using non-Gaussian states

Fumiya Hanamura
(
- U. Tokyo (main)
)
,
Warit Asavanant
(
- U. Tokyo (main)
)
,
Kosuke Fukui
(
- U. Tokyo (main)
)
,
Shunya Konno
(
- U. Tokyo (main)
)
,
Akira Furusawa
(
- U. Tokyo (main) and
- Wako, RIKEN
)

- Phys.Rev.A 104 (2021) 6, 062601
•
e-Print:
- 2102.05276
•
DOI:
- 10.1103/PhysRevA.104.062601

[24]

High-Fidelity Preparation, Gates, Memory, and Readout of a Trapped-Ion Quantum Bit

T. P. Harty
(
- Oxford U.
)
,
D. T. C. Allcock
(
- Oxford U.
)
,
C. J. Ballance
(
- Oxford U.
)
,
L. Guidoni
(
- Oxford U. and
- MPQ, Paris
)
,
H. A. Janacek
(
- Oxford U.
)

et al.

- Phys.Rev.Lett. 113 (2014) 22, 220501
•
DOI:
- 10.1103/PhysRevLett.113.220501

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