Mimo 5g(5年以上)研究综述
Mimo 5g 5年以上 - The obtained results prove that a regular and periodic triangular lattice is appealing for arrays to be adopted in massive MIMO 5G systems. [1] We further validate and demonstrate the advantages of DPS over various channel models of massive MIMO 5G technology by extensive simulations. [2] In this paper, we leverage channel charting for predicting the best Base Station (BS) beam to serve a given UE in a massive-MIMO 5G network. [3] This article overviews the new Flex Ethernet implementation agreement standardised by the Optical Internetworking Forum and its applicability for the transport of Massive MIMO 5G New Radio fronthaul traffic with deterministic delay. [4] This radiating device is designed with the microstrip feed for the massive-MIMO 5G requirements. [5] Besides, this paper constitutes a first step to the implementation of a mmWave MIMO 5G cooperative network platform. [6] The observed advantages offered by the triangular arrangement of antenna elements in terms of improved gain and SSE as well as the thermal aspect make it appealing for massive MIMO 5G applications. [7] Furthermore, this paper introduces the first study to develop an uplink mmWave MIMO 5G co-operative network platform through a Software Defined Radio (SDR) from a practical implementation point of view. [8] In this paper we use numerical modeling to assess exposure to a MU-MIMO 5G antenna in different built environments. [9] In this paper, we propose to exploit the unique characteristics of virtual channels to achieve efficient channel-based detection in millimeter-wave (mmWave)and massive MIMO 5G communications. [10] The space-time digital processing capability of the M-MIMO 5G base station is used to detect such signal. [11] Therefore, to solve these problems, this paper proposes a low-complexity hybrid beamforming scheme for mmWave Massive-MIMO 5G wireless networks. [12]所获得的结果证明,规则和周期性的三角形晶格对于在大规模 MIMO 5G 系统中采用阵列具有吸引力。 [1] 我们通过大量仿真进一步验证和展示了 DPS 相对于大规模 MIMO 5G 技术的各种信道模型的优势。 [2] 在本文中,我们利用信道图表来预测最佳基站 (BS) 波束,以服务于大规模 MIMO 5G 网络中的给定 UE。 [3] 本文概述了由光互联论坛标准化的新 Flex 以太网实施协议及其在具有确定性延迟的大规模 MIMO 5G 新无线电前传流量传输中的适用性。 [4] 该辐射设备采用微带馈电设计,可满足大规模 MIMO 5G 要求。 [5] 此外,本文构成了实施毫米波 MIMO 5G 协作网络平台的第一步。 [6] 天线元件的三角形排列在提高增益和 SSE 以及热方面提供的观察优势使其对大规模 MIMO 5G 应用具有吸引力。 [7] 此外,本文从实际实施的角度介绍了通过软件定义无线电 (SDR) 开发上行链路 mmWave MIMO 5G 协作网络平台的第一项研究。 [8] 在本文中,我们使用数值建模来评估不同建筑环境中 MU-MIMO 5G 天线的暴露情况。 [9] 在本文中,我们建议利用虚拟信道的独特特性,在毫米波 (mmWave) 和大规模 MIMO 5G 通信中实现高效的基于信道的检测。 [10] 利用 M-MIMO 5G 基站的时空数字处理能力来检测此类信号。 [11] 因此,为了解决这些问题,本文提出了一种用于mmWave Massive-MIMO 5G无线网络的低复杂度混合波束成形方案。 [12]
Massive Mimo 5g 海量 Mimo 5g
The obtained results prove that a regular and periodic triangular lattice is appealing for arrays to be adopted in massive MIMO 5G systems. [1] We further validate and demonstrate the advantages of DPS over various channel models of massive MIMO 5G technology by extensive simulations. [2] This article overviews the new Flex Ethernet implementation agreement standardised by the Optical Internetworking Forum and its applicability for the transport of Massive MIMO 5G New Radio fronthaul traffic with deterministic delay. [3] The observed advantages offered by the triangular arrangement of antenna elements in terms of improved gain and SSE as well as the thermal aspect make it appealing for massive MIMO 5G applications. [4] In this paper, we propose to exploit the unique characteristics of virtual channels to achieve efficient channel-based detection in millimeter-wave (mmWave)and massive MIMO 5G communications. [5]所获得的结果证明,规则和周期性的三角形晶格对于在大规模 MIMO 5G 系统中采用阵列具有吸引力。 [1] 我们通过大量仿真进一步验证和展示了 DPS 相对于大规模 MIMO 5G 技术的各种信道模型的优势。 [2] 本文概述了由光互联论坛标准化的新 Flex 以太网实施协议及其在具有确定性延迟的大规模 MIMO 5G 新无线电前传流量传输中的适用性。 [3] 天线元件的三角形排列在提高增益和 SSE 以及热方面提供的观察优势使其对大规模 MIMO 5G 应用具有吸引力。 [4] 在本文中,我们建议利用虚拟信道的独特特性,在毫米波 (mmWave) 和大规模 MIMO 5G 通信中实现高效的基于信道的检测。 [5]
Mmwave Mimo 5g 毫米波咪咪 5g
Besides, this paper constitutes a first step to the implementation of a mmWave MIMO 5G cooperative network platform. [1] Furthermore, this paper introduces the first study to develop an uplink mmWave MIMO 5G co-operative network platform through a Software Defined Radio (SDR) from a practical implementation point of view. [2]此外,本文构成了实施毫米波 MIMO 5G 协作网络平台的第一步。 [1] 此外,本文从实际实施的角度介绍了通过软件定义无线电 (SDR) 开发上行链路 mmWave MIMO 5G 协作网络平台的第一项研究。 [2]