Asynchronous distributed coordinated hybrid precoding in multi-cell mmWave wireless networks
Asynchronous distributed coordinated hybrid precoding in multi-cell mmWave wireless networks
Asynchronous distributed hybrid beamformers (ADBF) are conceived for minimizing the total transmit power subject to signal-to-interference-plus-noise ratio (SINR) constraints at the users. Our design requires only limited information exchange between the base stations (BSs) of the mmWave multi-cell coordinated (MCC) networks considered. To begin with, a semidefinite relaxation (SDR)-based fullydigital (FD) beamformer is designed for a centralized MCC system. Subsequently, a Bayesian learning (BL) technique is harnessed for decomposing the FD beamformer into its analog and baseband components and construct a hybrid transmit precoder (TPC). However, the centralized TPC design requires global channel state information (CSI), hence it results in a high signaling overhead. An alternating direction based method of multipliers (ADMM) technique is developed for a synchronous distributed beamformer (SDBF) design, which relies only on limited information exchange among the BSs, thus reducing the signaling overheads required by the centralized TPC design procedure. However, the SDBF design is challenging, since it requires the updates from the BSs to be strictly synchronized. As a remedy, an ADBF framework is developed that mitigates the inter-cell interference (ICI) and also control the asynchrony in the system. Furthermore, the above ADBF framework is also extended to the robust ADBF (R-ADBF) algorithm that incorporates the CSI uncertainty into the design procedure for minimizing the the worst-case transmit power. Our simulation results illustrate both the enhanced performance and the improved convergence properties of the ADMM-based ADBF and R-ADBF schemes.
CSI uncertainty, coordinated beamforming, inter-cell interference, mmWave MIMO, multi cell
200 - 218
Jafri, Meesam
46e4ee57-9ee8-4e2e-b4a9-6d26d7c796b8
Srivastava, Suraj
a90b79db-5004-4786-9e40-995bd5ce2606
Kumar, Sunil
67431e3d-b46f-4e8e-955c-82a0761c719a
Jagannatham, Aditya K.
ae9274e6-c98c-4e15-a5be-f4eb0fc179ff
Hanzo, Lajos
66e7266f-3066-4fc0-8391-e000acce71a1
25 January 2024
Jafri, Meesam
46e4ee57-9ee8-4e2e-b4a9-6d26d7c796b8
Srivastava, Suraj
a90b79db-5004-4786-9e40-995bd5ce2606
Kumar, Sunil
67431e3d-b46f-4e8e-955c-82a0761c719a
Jagannatham, Aditya K.
ae9274e6-c98c-4e15-a5be-f4eb0fc179ff
Hanzo, Lajos
66e7266f-3066-4fc0-8391-e000acce71a1
Jafri, Meesam, Srivastava, Suraj, Kumar, Sunil, Jagannatham, Aditya K. and Hanzo, Lajos
(2024)
Asynchronous distributed coordinated hybrid precoding in multi-cell mmWave wireless networks.
IEEE Open Journal of Vehicular Technology, 5, .
(doi:10.1109/OJVT.2023.3349151).
Abstract
Asynchronous distributed hybrid beamformers (ADBF) are conceived for minimizing the total transmit power subject to signal-to-interference-plus-noise ratio (SINR) constraints at the users. Our design requires only limited information exchange between the base stations (BSs) of the mmWave multi-cell coordinated (MCC) networks considered. To begin with, a semidefinite relaxation (SDR)-based fullydigital (FD) beamformer is designed for a centralized MCC system. Subsequently, a Bayesian learning (BL) technique is harnessed for decomposing the FD beamformer into its analog and baseband components and construct a hybrid transmit precoder (TPC). However, the centralized TPC design requires global channel state information (CSI), hence it results in a high signaling overhead. An alternating direction based method of multipliers (ADMM) technique is developed for a synchronous distributed beamformer (SDBF) design, which relies only on limited information exchange among the BSs, thus reducing the signaling overheads required by the centralized TPC design procedure. However, the SDBF design is challenging, since it requires the updates from the BSs to be strictly synchronized. As a remedy, an ADBF framework is developed that mitigates the inter-cell interference (ICI) and also control the asynchrony in the system. Furthermore, the above ADBF framework is also extended to the robust ADBF (R-ADBF) algorithm that incorporates the CSI uncertainty into the design procedure for minimizing the the worst-case transmit power. Our simulation results illustrate both the enhanced performance and the improved convergence properties of the ADMM-based ADBF and R-ADBF schemes.
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lajos (9)
- Accepted Manuscript
More information
Accepted/In Press date: 29 December 2023
e-pub ahead of print date: 3 January 2024
Published date: 25 January 2024
Keywords:
CSI uncertainty, coordinated beamforming, inter-cell interference, mmWave MIMO, multi cell
Identifiers
Local EPrints ID: 485908
URI: http://eprints.soton.ac.uk/id/eprint/485908
ISSN: 2644-1330
PURE UUID: 9e18a1c2-585b-4b6b-bd2d-23ed169b4a90
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Date deposited: 04 Jan 2024 02:06
Last modified: 21 Sep 2024 04:01
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Contributors
Author:
Meesam Jafri
Author:
Suraj Srivastava
Author:
Sunil Kumar
Author:
Aditya K. Jagannatham
Author:
Lajos Hanzo
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