Abstract
The hybrid design of precoding schemes for millimeter-wave communications allows exploiting the gains by using large antenna array with an affordable hardware cost and power consumption. In this work, we present a novel design strategy based on limiting the rank of the fully digital solutions before their decomposition into the analog and digital baseband components. This rank constraint on the digital formulation leads to a joint precoding and scheduling scheme where the number of allocated streams is limited according to the hardware constraints. In this way, the proposed approach can significantly reduce the performance losses caused by the direct decomposition of the unconstrained digital precoders. The resulting rank-constrained problems for the considered scenario are not convex and difficult to sort out. However, we propose several algorithms to compute the rank-constrained digital solutions with the help of the uplink-downlink duality for the achievable sum-rate. The obtained results show that this strategy achieves considerably higher sum-rates regardless of the channel conditions or available hardware resources.
Highlights
The fifth generation of cellular communications (5G) has been developed to satisfy challenging requirements in terms of traffic data, ultra-low latency and high transmission rates
We focus on massive Multiple-Input and MultipleOutput (MIMO) hybrid mmWave systems where all the radio frequency (RF) chains are connected to all the antennas
SIMULATION RESULTS we present the results obtained in different computer simulations carried out to evaluate the performance of the proposed approach and the different optimization algorithms
Summary
The fifth generation of cellular communications (5G) has been developed to satisfy challenging requirements in terms of traffic data, ultra-low latency and high transmission rates. For this reason, one of the key technologies proposed for the development of the 5G standard is the use of millimeter-wave (mmWave) [1]–[4]. One of the key technologies proposed for the development of the 5G standard is the use of millimeter-wave (mmWave) [1]–[4] These communications present a large attenuation and path losses because of using small wavelength signals [5], [6]. Conventional massive Multiple-Input and MultipleOutput (MIMO) schemes lead to an unaffordable hardware cost and power consumption, since one dedicated radio frequency (RF) chain operating at mmWave frequencies is necessary at each antenna [5], [8], [9].
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