2 research outputs found
Favorable Propagation with User Cluster Sharing
We examine the favorable propagation (FP) behavior of a massive multi-user
multiple-input-multiple-output (MU-MIMO) system equipped with a uniform linear
array (ULA), horizontal uniform rectangular array (HURA) or uniform circular
array (UCA) using a ray-based channel model with user cluster sharing. We
demonstrate FP for these systems and provide analytical expressions for the
mean-squared distance (MSD) of the FP metric from its large-system limit for
each of the aforementioned topologies. We use these results to examine the
detrimental effects of user cluster sharing on FP behavior, and demonstrate the
superior performance of the ULA as compared to the UCA and the HURA with equal
inter-element spacing. Although cluster sharing has a negative impact on FP for
finite arrays, we additionally examine the asymptotic rate of convergence to FP
as a function of array size and show that this rate is unchanged with or
without user cluster sharing.Comment: 7 pages, 3 figures, Accepted for publication in IEEE PIMRC 202
Performance of a dense urban massive MIMO network from a simulated ray-based channel
Massive MIMO network deployments are expected to be a key feature of the upcoming 5G communication systems. Such networks are able to achieve a high level of channel quality and can simultaneously serve multiple users with the same resources. In this paper, realistic massive MIMO channels are evaluated both in single and multi-cell environments. The favorable propagation property is evaluated in the single-cell scenario and provides perspectives on the minimal criteria required to achieve such conditions. The dense multi-cell urban scenario provides a comparison between linear, planar, circular, and cylindrical arrays to evaluate a large-scale multi-cell massive MIMO network. The system-level performance is predicted using two different kinds of channel models. First, a ray-based deterministic tool is utilized in a real North American city environment. Second, an independent and identically distributed (i.i.d.) Rayleigh fading channel model is considered, as often used in previously published massive MIMO studies. The analysis is conducted in a 16-macro-cell network with both randomly distributed outdoor and indoor users. It is shown that the physical array properties like the shape and configuration have a large impact on the throughput statistics. Although the system-level performance with i.i.d. Rayleigh fading can be close to the deterministic prediction in some situations (e.g., with large linear arrays), significant differences are noticed when considering other types of arrays. The differences in the performance of the various arrays utilizing the exact same network parameters and the same number of total antenna elements provide insights into the selection of these physical parameters for upcoming 5G networks.Funding Agencies|European Commission through the H2020-MSCA ETN-5Gwireless project [641985]</p