Joint Millimeter Wave and Microwave Resources Allocation in Cellular Networks with Dual-Mode Base Stations

Abstract

In this paper, a novel dual-mode scheduling framework is proposed that jointly performs user applications (UA) selection and scheduling over microwave (μW) and millimeter wave (mmW) bands. The proposed scheduling framework utilizes a set of context information, including the channel state information, the delay tolerance and required load per UA, and the uncertainty of mmW channels, to maximize the quality-of-service (QoS) per UA. The scheduling problem is formulated as an optimization with minimum unsatisfied relations (min-UR) problem which is shown to be challenging to solve. Consequently, a long-term scheduling framework, consisting of two stages, is proposed. Within this framework, first, the scheduling over μW band is formulated as a matching game and to solve this problem, a novel algorithm is proposed and shown to yield a two-sided stable resource allocation. Second, over the mmW band, the scheduling problem is formulated as a 0-1 Knapsack problem and a novel algorithm is proposed to solve it. Furthermore, it is shown that the proposed framework can find an effective scheduling solution, over both μW and mmW, in polynomial time. Simulation results show that, compared with conventional scheduling schemes, the proposed approach significantly increases the number of satisfied UAs and enhances the users' quality-of-experience.