Working towards final deployment, this book updates the research community on the current mmWave Massive MIMO roadmap, taking into account the future emerging technologies emanating from 3GPP/IEEE. New networking scenarios are identified, along with fundamental design requirements for mmWave Massive MIMO networks from an architectural and practical perspective. MmWave Massive MIMO: A Paradigm for 5G is the first book of its kind to hinge together related discussions on mmWave and Massive MIMO under the umbrella of 5G networks. Massive antenna arrays at the base stations can be deployed in collocated or. ASSIVE multiple-input multiple-output (MIMO), where a base station with many antennas simultaneously serves many users in the same time-frequency resource, is a promising 5G wireless access technology that can provide high throughput, reliability, and energy efciency with simple signal processing 2, 3.
While the traditional radio devices often have just two, four, or maximum eight TRX channels, the radio devices powered by Massive MIMO technology can have 32 or 64 TRX channels, with up to 512 or even more antenna elements, which can lead to. This technology leverages an aggressive spatial multiplexing, from using a large number of transmitting/receiving antennas, to multiply the capacity of a wireless channel.Massive MIMO, a large-scale antenna technology, is a core 5G technology that can improve network coverage, user experience and network capability. Analysis of Millimeter Wave and Massive MIMO Cellular NetworksMassive MIMO, where MIMO stands for multiple-input multiple-output, is widely expected to be a key enabler of 5G.
The analytical results demonstrate that with a sufficiently dense base station deployment, mmWave cellular networks are capable to achieve comparable SINR coverage and much higher rates than conventional networks. In the first contribution, I develop an mmWave cellular network model that incorporates the blockage effect and directional beamforming, and analyze the SINR and rate distributions as functions of the base station density, blockage parameters, and antenna geometry. The proposed models capture the key features of each technique, and allow for tractable signal-to-interference-plus-noise ratio (SINR) and rate analyses. In this dissertation, I develop stochastic geometry frameworks to analyze the system-level performance of mmWave, sub-6 GHz massive MIMO, and mmWave massive MIMO cellular networks. The prior frameworks for conventional cellular systems do not directly apply to analyze mmWave or massive MIMO networks, as (i) mmWave cellular networks differ in the different propagation conditions and hardware constraints and (ii) with a order of magnitude more antennas than conventional multi-user MIMO systems, massive MIMO systems will be operated in time-division duplex (TDD) mode, which renders pilot contamination a primary limiting factor. Of Millimeter Wave and Massive MIMO Cellular Networks Book Description :Millimeter wave (mmWave) communication and massive multiple-input multiple-output (MIMO) are promising techniques to increase system capacity in 5G cellular networks.
New networking scenarios are identified, along with fundamental design requirements for mmWave Massive MIMO networks from an architectural and practical perspective. I lev"mmWave Massive MIMO: A Paradigm for 5G" is the first book of its kind to hinge together related discussions on mmWave and Massive MIMO under the umbrella of 5G networks. In my third contribution, I extend the sub-6 GHz massive MIMO model to mmWave frequencies, by incorporating key mmWave features. Based on the analysis, I show scaling laws between the number of antennas and scheduled users per cell that maintain the uplink signal-to-interference ratio (SIR) distributions are different for maximum ratio combining (MRC) and zero-forcing (ZF) receivers.
The physical-layer design, multiple access control (MAC) mechanism and networking techniques are discussed for millimeter-wave communications aided by massive MIMO technology. This SpringerBrief also examines the selected applications of massive MIMO in 5G networks, i.e., massive MIMO-aided millimeter communications and energy transfer. Art physical-layer techniques and various networking techniques for interference mitigation and resource scheduling are introduced as well.
Every technological application presented is modeled in a schematic diagram and is considered in depth through mathematical analysis and performance assessment. It perfectly illustrates how the technology itself will benefit both individual consumers and industry as the world heads towards a more connected state of being. Advanced-level students studying communication engineering will also find this book useful as a secondary text.5G Physical Layer Technologies Book Description :Written in a clear and concise manner, this book presents readers with an in-depth discussion of the 5G technologies that will help move society beyond its current capabilities. Communication researchers in the area of MIMO technology, as well as researchers and practitioners working in millimeter communications and energy transfer seeking new research topics, and topic areas with communication system design, centralized and distributed algorithms, will find this brief useful as a reference. A downlink precoder and a uplink pilot scheme is proposed for single cell networks, and both non-cooperative and cooperative energy transfer in multi-cell are presented.
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