Millimeter wave–3D massive MIMO: Deep prior-aided graph neural network combining with hierarchical residual learning for beamspace channel estimation

IF 1.7 4区 计算机科学 Q3 ENGINEERING, ELECTRICAL & ELECTRONIC International Journal of Communication Systems Pub Date : 2024-07-23 DOI:10.1002/dac.5918
Haridoss Sudarsan, Krishnakumar Mahendran, Srinivasan Rathika, Subburaj Nagan Yoga Ananth
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Abstract

Millimeter Wave (mmWave) communication has emerged as a transformative technology at the forefront of wireless communication. One of the key challenges in harnessing the potential of mmWave technology is overcoming the increased susceptibility to propagation losses and environmental obstacles. To address these challenges, Three-Dimensional Massive Multiple-Input Multiple-Output (3D Massive MIMO) systems have gained traction. The 3D aspect extends this concept by considering the elevation dimension, allowing for enhanced spatial resolution and coverage. Accurate estimation of the channel in 3D Massive MIMO scenarios is particularly challenging because of the complex propagation characteristics of mmWave signals. This paper introduces an efficient-Aided Graph Neural Network Combining with Hierarchical Residual Learning (DPrGNN-HrResNetL), designed specifically for beamspace Channel Estimation (CE)in mmWave-Massive MIMO environments. The proposed model leverages deep priors and GNN mechanisms to enhance the extraction of spatial features, while hierarchical residual connections facilitate effective information flow through the network. DPrGNN enables the model to capture and understand complex spatial relationships among different antenna elements. The incorporation of deep priors provides a mechanism for leveraging prior knowledge about channel characteristics. This enhances the efficiency of the learning process, allowing the model to learn and adapt more effectively. The integration of hierarchical residual connections facilitates effective information flow through the network. This is particularly important for modeling complex dependencies within the beamspace channel data, enhancing the learning capacity of the network. The performance of the DPrGNN-HrResNetL model is evaluated across a range of Signal-to-Noise Ratios (SNRs), utilizing metrics such as Normalized Mean Squared Error (NMSE) to measure the accuracy of the estimation. The outcomes underscore the resilience and efficacy of the DPrGNN-HrResNetL approach in achieving precise CE within demanding mmWave scenarios.

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毫米波-3D 大规模 MIMO:深度先验辅助图神经网络与分层残差学习相结合用于波束空间信道估计
摘要毫米波(mmWave)通信已成为无线通信领域最前沿的变革性技术。利用毫米波技术潜力的关键挑战之一是克服传播损耗和环境障碍带来的更大影响。为了应对这些挑战,三维大规模多输入多输出(3D Massive MIMO)系统受到了广泛关注。三维多输入多输出(3D Massive MIMO)系统通过考虑海拔维度扩展了这一概念,从而提高了空间分辨率和覆盖范围。由于毫米波信号具有复杂的传播特性,因此在三维大规模多输入多输出场景中准确估计信道尤其具有挑战性。本文介绍了一种结合分层残差学习的高效辅助图神经网络(DPrGNN-HrResNetL),它是专为毫米波-大规模多输入多输出(MIMO)环境中的波束空间信道估计(CE)而设计的。所提出的模型利用深度先验和 GNN 机制来增强空间特征的提取,而分层残差连接则促进了网络中有效的信息流。DPrGNN 使模型能够捕捉和理解不同天线元件之间复杂的空间关系。深度先验的加入为利用有关信道特征的先验知识提供了一种机制。这提高了学习过程的效率,使模型能够更有效地学习和适应。分层残差连接的整合促进了信息在网络中的有效流动。这对于波束空间信道数据中复杂依赖关系的建模尤为重要,从而增强了网络的学习能力。DPrGNN-HrResNetL 模型的性能在一系列信噪比(SNR)范围内进行了评估,利用归一化均方误差(NMSE)等指标来衡量估计的准确性。结果表明,DPrGNN-HrResNetL 方法在要求苛刻的毫米波场景中实现精确的 CE 方面具有很强的适应性和有效性。
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来源期刊
CiteScore
5.90
自引率
9.50%
发文量
323
审稿时长
7.9 months
期刊介绍: The International Journal of Communication Systems provides a forum for R&D, open to researchers from all types of institutions and organisations worldwide, aimed at the increasingly important area of communication technology. The Journal''s emphasis is particularly on the issues impacting behaviour at the system, service and management levels. Published twelve times a year, it provides coverage of advances that have a significant potential to impact the immense technical and commercial opportunities in the communications sector. The International Journal of Communication Systems strives to select a balance of contributions that promotes technical innovation allied to practical relevance across the range of system types and issues. The Journal addresses both public communication systems (Telecommunication, mobile, Internet, and Cable TV) and private systems (Intranets, enterprise networks, LANs, MANs, WANs). The following key areas and issues are regularly covered: -Transmission/Switching/Distribution technologies (ATM, SDH, TCP/IP, routers, DSL, cable modems, VoD, VoIP, WDM, etc.) -System control, network/service management -Network and Internet protocols and standards -Client-server, distributed and Web-based communication systems -Broadband and multimedia systems and applications, with a focus on increased service variety and interactivity -Trials of advanced systems and services; their implementation and evaluation -Novel concepts and improvements in technique; their theoretical basis and performance analysis using measurement/testing, modelling and simulation -Performance evaluation issues and methods.
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