Abstract
In this paper, we explore reduced-connectivity radio frequency (RF) switching networks for reducing the analog hardware complexity and switching power losses in antenna selection (AS) systems. In particular, we analyze different hardware architectures for implementing the RF switching matrices required in AS designs with a reduced number of RF chains. We explicitly show that fully-flexible switching matrices, which facilitate the selection of any possible subset of antennas and attain the maximum theoretical sum rates of AS, present numerous drawbacks such as the introduction of significant insertion losses, particularly pronounced in massive multiple-input multiple-output (MIMO) systems. Since these disadvantages make fully-flexible switching suboptimal in the energy efficiency sense, we further consider partially-connected switching networks as an alternative switching architecture with reduced hardware complexity, which we characterize in this work. In this context, we also analyze the impact of reduced switching connectivity on the analog hardware and digital signal processing of AS schemes that rely on received signal power information. Overall, the analytical and simulation results shown in this paper demonstrate that partially-connected switching maximizes the energy efficiency of massive MIMO systems for a reduced number of RF chains, while fully-flexible switching offers sub-optimal energy efficiency benefits due to its significant switching power losses.
Highlights
T HE constant growth in the number of mobile devices as well as the development of data-hungry applications have driven the design of novel wireless communications solutions
II-B by use of radio frequency (RF) power meters, and b) the negligible performance loss introduced by this scheme when compared with the selection based on instantaneous channel state information (CSI) for the channels considered in this paper
SIMULATION RESULTS we present numerical results for characterizing the performance of the switching architectures considered in this paper
Summary
T HE constant growth in the number of mobile devices as well as the development of data-hungry applications have driven the design of novel wireless communications solutions. We present a number of specific hardware implementations of switching matrices that are optimized under different criteria such as the number of internal connections or the signal power losses In this context, we accurately characterize their insertion losses, which are shown to be critical for massive MIMO due to the large number of inputs (RF chains) and outputs (antennas) required. In contrast with [23]–[28], we consider architectures with limited connectivity as a means for reducing the complexity of the fully-flexible switching networks conventionally considered In this line, we determine the ergodic sum capacity loss introduced due to the limited connectivity for received signal powerbased AS systems, since power-based AS can offer a superior performance when practical CSI acquisition procedures are considered.
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