Litcius/Paper detail

Deep Learning for Radio Resource Allocation With Diverse Quality-of-Service Requirements in 5G

Rui Dong, Changyang She, Wibowo Hardjawana, Yonghui Li, Branka Vucetic

2020IEEE Transactions on Wireless Communications115 citationsDOI

Abstract

To accommodate diverse Quality-of-Service (QoS) requirements in 5th generation cellular networks, base stations need real-time optimization of radio resources in time-varying network conditions. This brings high computing overheads and long processing delays. In this work, we develop a deep learning framework to approximate the optimal resource allocation policy that minimizes the total power consumption of a base station by optimizing bandwidth and transmit power allocation. We find that a fully-connected neural network (NN) cannot fully guarantee the QoS requirements due to the approximation errors and quantization errors of the numbers of subcarriers. To tackle this problem, we propose a cascaded structure of NNs, where the first NN approximates the optimal bandwidth allocation, and the second NN outputs the transmit power required to satisfy the QoS requirement with given bandwidth allocation. Considering that the distribution of wireless channels and the types of services in the wireless networks are non-stationary, we apply deep transfer learning to update NNs in non-stationary wireless networks. Simulation results validate that the cascaded NNs outperform the fully connected NN in terms of QoS guarantee. In addition, deep transfer learning can reduce the number of training samples required to train the NNs remarkably.

Topics & Concepts

Computer scienceQuality of serviceResource allocationBase stationWireless networkBandwidth (computing)WirelessBandwidth allocationArtificial neural networkComputer networkCellular networkTransmitter power outputRadio resource managementArtificial intelligenceTransmitterTelecommunicationsChannel (broadcasting)Advanced MIMO Systems OptimizationAdvanced Wireless Communication TechnologiesEnergy Harvesting in Wireless Networks