Sub-6GHz assisted mmWave hybrid beamforming with heterogeneous graph neural network
Sub-6GHz assisted mmWave hybrid beamforming with heterogeneous graph neural network
In next-generation communications, sub-6GHz and millimeter-wave (mmWave) links typically coexist, with the sub- 6GHz link always active and the mmWave link active when high-rate transmission is required. Due to the spatial similarities between sub-6GHz and mmWave channels, sub-6GHz channel information can be utilized to support hybrid beamforming in mmWave communications to reduce overhead costs. We consider a multi-cell heterogeneous communication network where both sub-6GHz and mmWave communications co-exist. Multiple mmWave base stations (BSs) in the heterogeneous network simultaneously transmit signals to multiple users in their own mmWave cells while interfering with each other. The challenging problem is to design hybrid beamformers in the mmWave band that can maximize the system spectral efficiency. To address this highly complex programming using sub-6GHz information, a novel heterogeneous graph neural network (HGNN) architecture is proposed to learn the intrinsic relationship between sub-6GHz and mmWave and design the hybrid beamformers for mmWave BSs. The proposed HGNN consists of two different node types, namely, BS nodes and user equipment (UE) nodes, and two
different edge types, namely, desired link edge and interfering link edge. In addition, the attention mechanism and the residual structure are utilized in the HGNN architecture to improve the performance. Simulation results show that the proposed HGNN can successfully achieve better performances with sub-
6GHz information than traditional learning methods. The results also demonstrate that the attention mechanism and residual structure improve the performances of the HGNN compared to its unmodified counterparts.
Antenna arrays, Array signal processing, Computer architecture, Graph neural networks, Hybrid beamforming, Hybrid power systems, Millimeter wave communication, Radio frequency, graph neural network (GNN), machine learning, millimeter wave communications, out-of-band information
6917-6928
Huang, Zhaohui
19be76c4-801f-420f-98c9-98942cc36e5e
Wang, Zhaocheng
70339538-3970-4094-bcfc-1b5111dfd8b4
Chen, Sheng
9310a111-f79a-48b8-98c7-383ca93cbb80
20 November 2024
Huang, Zhaohui
19be76c4-801f-420f-98c9-98942cc36e5e
Wang, Zhaocheng
70339538-3970-4094-bcfc-1b5111dfd8b4
Chen, Sheng
9310a111-f79a-48b8-98c7-383ca93cbb80
Huang, Zhaohui, Wang, Zhaocheng and Chen, Sheng
(2024)
Sub-6GHz assisted mmWave hybrid beamforming with heterogeneous graph neural network.
IEEE Transactions on Communications, 72 (11), , [10538322].
(doi:10.1109/TCOMM.2024.3405372).
Abstract
In next-generation communications, sub-6GHz and millimeter-wave (mmWave) links typically coexist, with the sub- 6GHz link always active and the mmWave link active when high-rate transmission is required. Due to the spatial similarities between sub-6GHz and mmWave channels, sub-6GHz channel information can be utilized to support hybrid beamforming in mmWave communications to reduce overhead costs. We consider a multi-cell heterogeneous communication network where both sub-6GHz and mmWave communications co-exist. Multiple mmWave base stations (BSs) in the heterogeneous network simultaneously transmit signals to multiple users in their own mmWave cells while interfering with each other. The challenging problem is to design hybrid beamformers in the mmWave band that can maximize the system spectral efficiency. To address this highly complex programming using sub-6GHz information, a novel heterogeneous graph neural network (HGNN) architecture is proposed to learn the intrinsic relationship between sub-6GHz and mmWave and design the hybrid beamformers for mmWave BSs. The proposed HGNN consists of two different node types, namely, BS nodes and user equipment (UE) nodes, and two
different edge types, namely, desired link edge and interfering link edge. In addition, the attention mechanism and the residual structure are utilized in the HGNN architecture to improve the performance. Simulation results show that the proposed HGNN can successfully achieve better performances with sub-
6GHz information than traditional learning methods. The results also demonstrate that the attention mechanism and residual structure improve the performances of the HGNN compared to its unmodified counterparts.
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Sub-6GHz_TCOM
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Accepted/In Press date: 18 May 2024
e-pub ahead of print date: 24 May 2024
Published date: 20 November 2024
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Publisher Copyright:
IEEE
Keywords:
Antenna arrays, Array signal processing, Computer architecture, Graph neural networks, Hybrid beamforming, Hybrid power systems, Millimeter wave communication, Radio frequency, graph neural network (GNN), machine learning, millimeter wave communications, out-of-band information
Identifiers
Local EPrints ID: 490431
URI: http://eprints.soton.ac.uk/id/eprint/490431
ISSN: 0090-6778
PURE UUID: 1884c68d-8650-48da-b5ee-149902b22080
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Date deposited: 28 May 2024 16:38
Last modified: 20 Nov 2024 17:46
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Contributors
Author:
Zhaohui Huang
Author:
Zhaocheng Wang
Author:
Sheng Chen
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