Abstract
The fifth generation and beyond wireless communication will support vastly heterogeneous services and user demands such as massive connection, low latency and high transmission rate. Network slicing has been envisaged as an efficient technology to meet these diverse demands. In this paper, we propose a dynamic virtual resources allocation scheme based on the radio access network (RAN) slicing for uplink communications to ensure the quality-of-service (QoS). To maximum the weighted-sum transmission rate performance under delay constraint, formulate a joint optimization problem of subchannel allocation and power control as an infinite-horizon average-reward constrained Markov decision process (CMDP) problem. Based on the equivalent Bellman equation, the optimal control policy is first derived by the value iteration algorithm. However, the optimal policy suffers from the widely known curse-of-dimensionality problem. To address this problem, the linear value function approximation (approximate dynamic programming) is adopted. Then, the subchannel allocation Q-factor is decomposed into the per-slice Q-factor. Furthermore, the Q-factor and Lagrangian multipliers are updated by the use of an online stochastic learning algorithm. Finally, simulation results reveal that the proposed algorithm can meet the delay requirements and improve the user transmission rate compared with baseline schemes.
Highlights
Driven by an astounding increase of mobile users and their bandwidth-hungry and varied applications, wireless data traffic will growth exponentially in the couple years [1], [2]
Due to the system states change dynamically with time, the resource manager dynamically adjust subchannel allocation and power control strategy in real-time based on global channel state information (CSI) (GCSI), global queue state information (QSI) (GQSI) and global energy state information (ESI) (GESI)
The Distributed Online Learning Algorithm using Stochastic Approximation needs to obtain according to the slice CSI (SCSI), slice QSI (SQSI) and slice ESI (SESI), which is summarized in the following
Summary
Driven by an astounding increase of mobile users and their bandwidth-hungry and varied applications, wireless data traffic will growth exponentially in the couple years [1], [2]. In RAN slicing, operators allocate resources efficiently and flexibly at the network level according to different performance requirements of users. In [18], a cell planning scheme for network slicing was proposed to maximize the resource efficiency under different QoS requirements of different mobile services for wireless communications. This scheme jointly optimized the inter-slice resource allocation, the distribution of cells operated on different slices, and the users allocation for cells. The adjustment action of power control of virtual resource allocation of downlink RAN slicing, the problem was described as a CMDP aiming at maximizing the total user rate.
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