Abstract
Power Control (PC) can coordinate mutual interference between cells in heterogeneous cellular networks (HCNs). Most of the existing works focus on real-time PC problems based on instantaneous channel state information (CSI) for all users. However, such scheme may result in low feasible probability and high energy consumption. If the PC problem is frequently infeasible, the users that require low latency communications will fail to get services in time. In this paper, we classify the users into two categories according to their sensitivity to latency: delay-sensitive-users (DSUs) and non-delay-sensitive-users (NDSUs). We use instantaneous signal-to-interference-plus-noise-ratio (SINR) constraints to ensure the success of data transmission per time slot to meet DSUs’ low latency requirements, and the long-term mean data rate constraints to ensure NDSUs’ average data rate requirements. On the one hand, the long-term constraints allow the system to sacrifice NDSUs’ short-term performance to guarantee DSUs’ instantaneous performance when the channel condition is poor. On the other hand, the system will appropriately improve NDSUs’ performance to ensure their target mean data rate when the channel condition is good. Under this scheme, we formulate the PC problems under perfect CSI, bounded CSI error and stochastic CSI error scenarios as a uniform problem, which is a non-convex stochastic constrained problem. The recently proposed constrained stochastic successive convex approximation (CSSCA) technique is utilized to handle this problem. Simulation results show that the proposed scheme can significantly improve the feasible probability of DSUs’ instantaneous constraints and reduce the network’s energy consumption.
Highlights
The fifth-generation (5G) cellular network is targeting to achieve 1000× capacity increase and millisecond-level lowlatency solutions [1]
We use long-term mean data rate constraints to formulate the requirements of NDSUs to relax the original instantaneous power control (PC) problem and more resources are reserved for DSUs to meet their strict low-latency requirements
In the communication systems, where the channel reciprocity holds between uplink and downlink and the channel state information (CSI) is obtained through uplink channel estimation, the CSI error is mainly caused by the interference and noise at the receivers [23]
Summary
The fifth-generation (5G) cellular network is targeting to achieve 1000× capacity increase and millisecond-level lowlatency solutions [1]. The robust resource allocation designs are developed under two types of CSI errors, i.e., bounded and stochastic CSI error [8] The former assumes that the CSI is bounded in an uncertainty region. The authors in [14] investigate the optimal power allocation scheme to maximize the energy efficiency and secrecy of wireless networks. Even if the PC problem is feasible, it will consume high energy to meet the instantaneous requirements of all users To address these issues, we use long-term mean data rate constraints to formulate the requirements of NDSUs to relax the original instantaneous PC problem and more resources are reserved for DSUs to meet their strict low-latency requirements. In order to cope with the inevitable channel uncertainty, we consider the PC under the bounded and the statistical CSI error scenarios.
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