Abstract
Achieving energy efficiency (EE) fairness among heterogeneous mobile devices will become a crucial issue in future wireless networks. This paper investigates a deep learning (DL) approach for improving EE fairness performance in interference channels (IFCs) where multiple transmitters simultaneously convey data to their corresponding receivers. To improve the EE fairness, we aim to maximize the minimum EE among multiple transmitter–receiver pairs by optimizing the transmit power levels. Due to fractional and max-min formulation, the problem is shown to be non-convex, and, thus, it is difficult to identify the optimal power control policy. Although the EE fairness maximization problem has been recently addressed by the successive convex approximation framework, it requires intensive computations for iterative optimizations and suffers from the sub-optimality incurred by the non-convexity. To tackle these issues, we propose a deep neural network (DNN) where the procedure of optimal solution calculation, which is unknown in general, is accurately approximated by well-designed DNNs. The target of the DNN is to yield an efficient power control solution for the EE fairness maximization problem by accepting the channel state information as an input feature. An unsupervised training algorithm is presented where the DNN learns an effective mapping from the channel to the EE maximizing power control strategy by itself. Numerical results demonstrate that the proposed DNN-based power control method performs better than a conventional optimization approach with much-reduced execution time. This work opens a new possibility of using DL as an alternative optimization tool for the EE maximizing design of the next-generation wireless networks.
Highlights
For the last decade, energy efficiency (EE) of wireless communication systems, which measures the effectiveness of the power consumption utilized for the data transmission, has been emerging as an important performance metric for the next-generation networking scenarios including wireless sensor networks, device-to-device communications, and internet-of-things (IoT) systems [1,2,3,4,5,6,7,8,9,10]
This paper studies a deep learning (DL) method for improving the EE fairness performance in the interference channels (IFCs)
The EE fairness maximization has been recently addressed by using the successive convex approximation (SCA) framework, such a traditional optimization approach suffers from high computational complexity for the iterations and the optimality loss
Summary
Energy efficiency (EE) of wireless communication systems, which measures the effectiveness of the power consumption utilized for the data transmission, has been emerging as an important performance metric for the next-generation networking scenarios including wireless sensor networks, device-to-device communications, and internet-of-things (IoT) systems [1,2,3,4,5,6,7,8,9,10]. The fractional programming framework was employed in [1,2] to address the EE maximization problems in various configurations. Due to the multi-cell and multi-user interference terms, the weighted sum EE maximization problems are no longer convex and cannot be tackled by the off-the-shelf convex optimization software
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