Network-level ISAC: an analytical study of antenna topologies ranging from massive to cell-free MIMO
Network-level ISAC: an analytical study of antenna topologies ranging from massive to cell-free MIMO
A cooperative architecture is proposed for integrated sensing and communication (ISAC) networks, incorporating coordinated multi-point (CoMP) transmission along with multi-static sensing. We investigate how the allocation of antennas-to-base stations (BSs) affects cooperative sensing and cooperative communication performance. More explicitly, we balance the benefits of geographically concentrated antennas in the massive multiple input multiple output (MIMO) fashion, which enhance beamforming and coherent processing, against those of geographically distributed antennas towards cell-free transmission, which improve diversity and reduce service distances. Regarding sensing performance, we investigate three localization methods: angle-of-arrival (AOA)- based, time-of-flight (TOF)-based, and a hybrid approach combining both AOA and TOF measurements, for critically appraising their effects on ISAC network performance. Our analysis shows that in networks having N ISAC nodes following a Poisson point process, the localization accuracy of TOF-based methods follows a ln2 N scaling law (explicitly, the Cramér-Rao lower bound (CRLB) reduces with ln2 N). The AOA-based methods follow a ln N scaling law, while the hybrid methods scale as a ln2 N+b ln N, where a and b represent parameters related to TOF and AOA measurements, respectively. The difference between these scaling laws arises from the distinct ways in which measurement results are converted into the target location. Specifically, when converting AOA measurements to the target location, the localization error introduced during this conversion is inversely proportional to the distance between the BS and the target, leading to a more significant reduction in accuracy as the number of transceivers increases. In contrast, TOF-based localization avoids such distance dependent errors in the conversion process. In terms of communication performance, we derive a tractable expression for the communication data rate, considering various cooperative region sizes and antenna-to-BS allocation strategy. It is proved that higher path loss exponents favor distributed antenna allocation to reduce access distances, while lower exponents favor centralized antenna allocation to maximize beamforming gain. Simulations confirm that cooperative transmission and sensing in ISAC networks can effectively improve non-cooperative sensing and communication performance The proposed cooperative scheme shows superior performance improvement compared to centralized or distributed antenna allocation strategies.
Meng, Kaitao
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Han, Kawon
96c7140e-9558-4c09-9dff-97cc6ab6d200
Masouros, Christos
f7d74183-a31b-412e-8a75-1a942aa156d8
Hanzo, Lajos
66e7266f-3066-4fc0-8391-e000acce71a1
Meng, Kaitao
f946d1d2-4962-4f03-ba2f-a390145242c7
Han, Kawon
96c7140e-9558-4c09-9dff-97cc6ab6d200
Masouros, Christos
f7d74183-a31b-412e-8a75-1a942aa156d8
Hanzo, Lajos
66e7266f-3066-4fc0-8391-e000acce71a1
Meng, Kaitao, Han, Kawon, Masouros, Christos and Hanzo, Lajos
(2025)
Network-level ISAC: an analytical study of antenna topologies ranging from massive to cell-free MIMO.
IEEE Transactions on Wireless Communications.
(doi:10.1109/TWC.2025.3576432).
Abstract
A cooperative architecture is proposed for integrated sensing and communication (ISAC) networks, incorporating coordinated multi-point (CoMP) transmission along with multi-static sensing. We investigate how the allocation of antennas-to-base stations (BSs) affects cooperative sensing and cooperative communication performance. More explicitly, we balance the benefits of geographically concentrated antennas in the massive multiple input multiple output (MIMO) fashion, which enhance beamforming and coherent processing, against those of geographically distributed antennas towards cell-free transmission, which improve diversity and reduce service distances. Regarding sensing performance, we investigate three localization methods: angle-of-arrival (AOA)- based, time-of-flight (TOF)-based, and a hybrid approach combining both AOA and TOF measurements, for critically appraising their effects on ISAC network performance. Our analysis shows that in networks having N ISAC nodes following a Poisson point process, the localization accuracy of TOF-based methods follows a ln2 N scaling law (explicitly, the Cramér-Rao lower bound (CRLB) reduces with ln2 N). The AOA-based methods follow a ln N scaling law, while the hybrid methods scale as a ln2 N+b ln N, where a and b represent parameters related to TOF and AOA measurements, respectively. The difference between these scaling laws arises from the distinct ways in which measurement results are converted into the target location. Specifically, when converting AOA measurements to the target location, the localization error introduced during this conversion is inversely proportional to the distance between the BS and the target, leading to a more significant reduction in accuracy as the number of transceivers increases. In contrast, TOF-based localization avoids such distance dependent errors in the conversion process. In terms of communication performance, we derive a tractable expression for the communication data rate, considering various cooperative region sizes and antenna-to-BS allocation strategy. It is proved that higher path loss exponents favor distributed antenna allocation to reduce access distances, while lower exponents favor centralized antenna allocation to maximize beamforming gain. Simulations confirm that cooperative transmission and sensing in ISAC networks can effectively improve non-cooperative sensing and communication performance The proposed cooperative scheme shows superior performance improvement compared to centralized or distributed antenna allocation strategies.
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Paper-TW-Oct-24-2221.R1 Final PDF
- Accepted Manuscript
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Accepted/In Press date: 28 May 2025
e-pub ahead of print date: 11 June 2025
Identifiers
Local EPrints ID: 503014
URI: http://eprints.soton.ac.uk/id/eprint/503014
ISSN: 1536-1276
PURE UUID: 01876ccd-d279-41ff-bdc0-48fc3995f309
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Date deposited: 16 Jul 2025 16:30
Last modified: 17 Jul 2025 01:40
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Contributors
Author:
Kaitao Meng
Author:
Kawon Han
Author:
Christos Masouros
Author:
Lajos Hanzo
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