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1Q: first-generation wireless systems integrating classical and quantum communication

1Q: first-generation wireless systems integrating classical and quantum communication
1Q: first-generation wireless systems integrating classical and quantum communication
We introduce the concept of 1Q, the first wireless generation of integrated classical and quantum communication. 1Q features quantum base stations (QBSs) that support entanglement distribution via free-space optical links alongside traditional radio communications. Key new components include quantum cells, quantum user equipment (QUEs), and hybrid resource allocation spanning classical time-frequency and quantum entanglement domains. Several application scenarios are discussed and illustrated through system design requirements for quantum key distribution, blind quantum computing, and distributed quantum sensing. A range of unique quantum constraints are identified, including decoherence timing, fidelity requirements, and the interplay between quantum and classical error probabilities. Protocol adaptations extend cellular connection management to incorporate entanglement generation, distribution, and handover procedures, expanding the Quantum Internet to the cellular wireless.
1556-6072
2-17
Popovski, Petar
b3301fc8-3376-460c-ab01-40c789c2103c
Stefanovic, Cedomir
27ef621b-000e-4064-bba7-ecfada290c84
Soret, Beatriz
5591418e-ada3-4d5f-b376-f147c019e03a
Leyva-Mayorga, Israel
e91f3761-6262-4aeb-983e-29fdac36dcae
Raj Pandey, Shashi
39b4b066-7b19-48d3-a86b-77d29f72f75a
B. Christensen, René
548b5faa-868d-40ee-91f8-55de0fe85bf3
K. Søndergaard, Jakob
74b45688-f132-4d07-aed4-771cb1eff9ad
S. Jensen, Kristian
58f0b5cd-2664-4d4e-8c76-2fb515f565ff
G. Pedersen, Thomas
3c1c9f00-2659-478c-8bfd-2920e34f8804
Sara Cacciapuoti, Angela
2f664c06-b8ea-4258-a877-3ce42a556390
Hanzo, Lajos
66e7266f-3066-4fc0-8391-e000acce71a1
Popovski, Petar
b3301fc8-3376-460c-ab01-40c789c2103c
Stefanovic, Cedomir
27ef621b-000e-4064-bba7-ecfada290c84
Soret, Beatriz
5591418e-ada3-4d5f-b376-f147c019e03a
Leyva-Mayorga, Israel
e91f3761-6262-4aeb-983e-29fdac36dcae
Raj Pandey, Shashi
39b4b066-7b19-48d3-a86b-77d29f72f75a
B. Christensen, René
548b5faa-868d-40ee-91f8-55de0fe85bf3
K. Søndergaard, Jakob
74b45688-f132-4d07-aed4-771cb1eff9ad
S. Jensen, Kristian
58f0b5cd-2664-4d4e-8c76-2fb515f565ff
G. Pedersen, Thomas
3c1c9f00-2659-478c-8bfd-2920e34f8804
Sara Cacciapuoti, Angela
2f664c06-b8ea-4258-a877-3ce42a556390
Hanzo, Lajos
66e7266f-3066-4fc0-8391-e000acce71a1

Popovski, Petar, Stefanovic, Cedomir, Soret, Beatriz, Leyva-Mayorga, Israel, Raj Pandey, Shashi, B. Christensen, René, K. Søndergaard, Jakob, S. Jensen, Kristian, G. Pedersen, Thomas, Sara Cacciapuoti, Angela and Hanzo, Lajos (2025) 1Q: first-generation wireless systems integrating classical and quantum communication. IEEE Vehicular Technology Magazine, 2-17. (doi:10.1109/MVT.2025.3622826).

Record type: Article

Abstract

We introduce the concept of 1Q, the first wireless generation of integrated classical and quantum communication. 1Q features quantum base stations (QBSs) that support entanglement distribution via free-space optical links alongside traditional radio communications. Key new components include quantum cells, quantum user equipment (QUEs), and hybrid resource allocation spanning classical time-frequency and quantum entanglement domains. Several application scenarios are discussed and illustrated through system design requirements for quantum key distribution, blind quantum computing, and distributed quantum sensing. A range of unique quantum constraints are identified, including decoherence timing, fidelity requirements, and the interplay between quantum and classical error probabilities. Protocol adaptations extend cellular connection management to incorporate entanglement generation, distribution, and handover procedures, expanding the Quantum Internet to the cellular wireless.

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e-pub ahead of print date: 13 October 2025
Learn more about Next Generation Wireless research

Identifiers

Local EPrints ID: 506755
URI: http://eprints.soton.ac.uk/id/eprint/506755
DOI: doi:10.1109/MVT.2025.3622826
ISSN: 1556-6072
PURE UUID: c58ed66b-d842-4aad-a15f-58e87f117ff5
ORCID for Lajos Hanzo: ORCID iD orcid.org/0000-0002-2636-5214

Catalogue record

Date deposited: 18 Nov 2025 17:35
Last modified: 19 Nov 2025 02:32

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Contributors

Author: Petar Popovski
Author: Cedomir Stefanovic
Author: Beatriz Soret
Author: Israel Leyva-Mayorga
Author: Shashi Raj Pandey
Author: René B. Christensen
Author: Jakob K. Søndergaard
Author: Kristian S. Jensen
Author: Thomas G. Pedersen
Author: Angela Sara Cacciapuoti
Author: Lajos Hanzo ORCID iD

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