Abstract
In a joint transmission coordinated multipoint (JT-CoMP) system, a shared spectrum is utilized by all neighbor cells. In the downlink, a group of base stations (BSs) coordinately transmit the users’ data to avoid serious interference at the users in the boundary of the cells, thus substantially improving area fairness. However, this comes at the cost of high feedback and backhaul load; In a frequency division duplex system, all users at the cell boundaries have to collect and send feedback of the downlink channel state information (CSI). In centralized JT-CoMP, although with capabilities for perfect coordination, a central coordination node have to send the computed precoding weights and corresponding data to all cells which can overwhelm the backhaul resources. In this paper, we design a JT-CoMP scheme, by which the sum of the mean square error (MSE) at the boundary users is minimized, while feedback and backhaul loads are constrained and the load is balanced between BSs. Our design is based on the singular value decomposition of CSI matrix and optimization of a binary link selection matrix to provide sparse feedback—constrained backhaul link. For comparison, we adopt the previously presented schemes for feedback and backhaul reduction in the physical layer. Extensive numerical evaluations show that the proposed scheme can reduce the MSE with at least 25%, compared to the adopted and existing schemes.
Highlights
Mobile communication systems are becoming an essential part of social networks, interactive media, internet of things (IoT), and a facilitator for the digital economy
This drives the fifth-generation and beyond (B5G) of mobile communication systems to scale mainly in three dimensions; (a) Rate is scaled to 10 Gbps which is ten-times of peak data rate in the fourth generation (4G) of long term evolution (LTE), release 10, and end-to-end latency decreases to 1 ms which is one-fifth of latency compared to 4G. (b) A massive scale in the number of connected devices in Nezafati et al J Wireless Com Network (2021) 2021:103
The link selection matrix is designed, providing required feedback and backhaul load reductions and load balancing between Base station (BS)
Summary
Mobile communication systems are becoming an essential part of social networks, interactive media (e.g. augmented and virtual reality), internet of things (IoT), and a facilitator for the digital economy. (c) Higher system reliability and quicker round trip times are to be available in transportation systems and industrial process control. To fulfill these requirements, a combination of various new techniques such as massive multiple input multiple output (MMIMO), dense small cells, cooperative communications such as device-todevice (D2D) and coordinated multipoint (CoMP), advanced air interface, additional spectrum at higher frequencies (mm-wave), and integrated access and backhaul (IAB) are needed [1,2,3,4,5]. 5G enhanced some aspects of CoMP such as control signaling and channel feedback [10, 11]
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