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Abstract
Cognitive radio (CR) is a critical technique to solve the conflict between the explosive growth of traffic and severe spectrum scarcity. Reasonable radio resource allocation with CR can effectively achieve spectrum sharing and co-channel interference (CCI) mitigation. In this paper, we propose a joint channel selection and power adaptation scheme for the underlay cognitive radio network (CRN), maximizing the data rate of all secondary users (SUs) while guaranteeing the quality of service (QoS) of primary users (PUs). To exploit the underlying topology of CRNs, we model the communication network as dynamic graphs, and the random walk is used to imitate the users’ movements. Considering the lack of accurate channel state information (CSI), we use the user distance distribution contained in the graph to estimate CSI. Moreover, the graph convolutional network (GCN) is employed to extract the crucial interference features. Further, an end-to-end learning model is designed to implement the following resource allocation task to avoid the split with mismatched features and tasks. Finally, the deep reinforcement learning (DRL) framework is adopted for model learning, to explore the optimal resource allocation strategy. The simulation results verify the feasibility and convergence of the proposed scheme, and prove that its performance is significantly improved.
Highlights
With the deployment of the fifth-generation (5G) mobile communication system, users are provided with better quality of service (QoS) and quality of experience (QoE), with extremely high data rates and diversified service provisioning [1]
As a means to boost the performance of 5G wireless communication systems, cognitive radio (CR) has successfully attracted the attention of industry and academia
We propose a method of constructing the topology of the underlay cognitive radio network (CRN) based on a dynamic graph
Summary
With the deployment of the fifth-generation (5G) mobile communication system, users are provided with better quality of service (QoS) and quality of experience (QoE), with extremely high data rates and diversified service provisioning [1]. The work in [25] proposes a novel graph embedding-based method for link scheduling in D2D networks and develops a K-nearest neighbor graph representation method to reduce the computational complexity Even though these methods are scalable to large-size wireless communication networks, the process of feature extraction and resource allocation are separated. An end-to-end learning model, namely the graph convolutional network (GCN), is adopted to explore the performance of resource management in the underlay CRN. We design an end-to-end model by stacking the graph convolutional layers, to learn the structural information and attribute the information of the CRN communication graph In this design, the convolutional layers are mainly used to extract interference features, and the fully connected layers are responsible for allocating the channel and power.
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