Flexible Base Station Sleeping and Resource Cooperation Enabled Green Fully-Decoupled RAN

Base station (BS) sleeping, a promising technique to address the growing energy consumption in wireless communication networks, encounters challenges such as coverage holes and coupled uplink and downlink transmissions. As an innovative architecture designed for future-generation mobile communication networks, the fully-decoupled radio access network (FD-RAN) is anticipated to overcome these challenges by fully decoupled control-data planes and uplink-downlink transmissions. In this paper, we investigate energy-efficient uplink FD-RAN leveraging flexible BS sleeping and resource cooperation. First, we introduce a holistic energy consumption model and formulate a bi-level energy efficiency maximizing problem for FD-RAN, involved with the joint optimization of user equipment (UE) association, BS sleeping, and power control. Subsequently, through employing the Tammer decomposition method, the formulated bi-level problem is converted into two equivalent upper-level and lower-level problems. The lower-level problem encompassed with UE power control is addressed by introducing a successive lower-bound maximization-based Dinkelbach's algorithm, and the upper-level problem for UE association and BS sleeping is solved through a modified low-complexity many-to-many swap matching algorithm, respectively. Extensive simulation results not only demonstrate the superior effectiveness of FD-RAN and our proposed algorithms but also reveal the sources of energy efficiency gains within FD-RAN.