A Deep Learning Framework for Optimization of MISO Downlink Beamforming

Xia, Wenchao; Zheng, Gan; Zhu, Yongxu; Zhang, Jun; Wang, Jiangzhou; Petropulu, Athina P.

doi:10.1109/tcomm.2019.2960361

Cited by 243 publications

(209 citation statements)

References 78 publications

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“…Based on results in Theorem 1, next we find solutions through designing the neural networks with the DL technique. Similar to our previous work [47], we introduce a general DL structure to approximate the mapping function from the channel coefficients to the beamforming solutions, as shown in Fig. 2.…”

Section: A a General DL Structurementioning

confidence: 99%

“…The adopted DL structure includes two main modules: the neural network module and the signal processing module [51]. Here we give a short description about the two modules, and for more details readers are referred to [47]. MSE Figure 2.…”

Section: A a General DL Structurementioning

confidence: 99%

“…The learned key features and the functionalities in the signal processing module are designated according to the expert knowledge. Note that the expert knowledge is problem-dependent and has no unified form, but what is in common is that the expert knowledge can significantly reduce the number of variables to be predicted compared to the beamforming matrix [47]. For example, the dual forms of the original problems are the typical expert knowledge for beamforming optimization.…”

Section: ) Neural Network Modulementioning

confidence: 99%

“…However, there are few works that focus on the learning approach to optimize the beamforming design in multiantenna communications, with the exception of [42], [43], [44], [45], [46], [47]. The difficulty is partly due to the large number of complex variables contained in the beamforming matrix that need to be optimized.…”

Section: Introductionmentioning

confidence: 99%

See 3 more Smart Citations

Deep Learning Enabled Optimization of Downlink Beamforming Under Per-Antenna Power Constraints: Algorithms and Experimental Demonstration

Zhang

Xia

You

et al. 2020

IEEE Trans. Wireless Commun.

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This paper studies fast downlink beamforming algorithms using deep learning in multiuser multiple-inputsingle-output systems where each transmit antenna at the base station has its own power constraint. We focus on the signal-to-interference-plus-noise ratio (SINR) balancing problem which is quasi-convex but there is no efficient solution available. We first design a fast subgradient algorithm that can achieve near-optimal solution with reduced complexity. We then propose a deep neural network structure to learn the optimal beamforming based on convolutional networks and exploitation of the duality of the original problem. Two strategies of learning various dual variables are investigated with different accuracies, and the corresponding recovery of the original solution is facilitated by the subgradient algorithm. We also develop a generalization method of the proposed algorithms so that they can adapt to the varying number of users and antennas without re-training. We carry out intensive numerical simulations and testbed experiments to evaluate the performance of the proposed algorithms. Results show that the proposed algorithms achieve close to optimal solution in simulations with perfect channel information and outperform the alleged theoretically optimal solution in experiments, illustrating a better performance-complexity tradeoff than existing schemes.Index Terms-Deep learning, beamforming, MISO, SINR balancing, per-antenna power constraints. ).We gratefully acknowledge the support of NVIDIA Corporation with the donation of a Titan Xp GPU used for this research.

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Section: A a General DL Structurementioning

confidence: 99%

Section: A a General DL Structurementioning

confidence: 99%

Section: ) Neural Network Modulementioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Deep Learning Enabled Optimization of Downlink Beamforming Under Per-Antenna Power Constraints: Algorithms and Experimental Demonstration

Zhang

Xia

You

et al. 2020

IEEE Trans. Wireless Commun.

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“…The approach means that most complexity is shifted to offline training an artificial neural network (NN) with a large dataset [4]. An online solution can then be obtained by going through a trained NN generalizable from the dataset, with some simple linear and standard nonlinear operations [5]. Researchers have applied DL to network deployment and planning, resource management, and network operation and maintenance.…”

Section: Introductionmentioning

confidence: 99%

Model-Driven Beamforming Neural Networks

Xia

Zheng

Wong

et al. 2020

IEEE Wireless Commun.

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Beamforming is evidently a core technology in recent generations of mobile communication networks. Nevertheless, an iterative process is typically required to optimize the parameters, making it ill-placed for real-time implementation due to high complexity and computational delay. Heuristic solutions such as zero-forcing (ZF) are simpler but at the expense of performance loss. Alternatively, deep learning (DL) is well understood to be a generalizing technique that can deliver promising results for a wide range of applications at much lower complexity if it is sufficiently trained. As a consequence, DL may present itself as an attractive solution to beamforming. To exploit DL, this article introduces general data-and model-driven beamforming neural networks (BNNs), presents various possible learning strategies, and also discusses complexity reduction for the DL-based BNNs. We also offer enhancement methods such as training-set augmentation and transfer learning in order to improve the generality of BNNs, accompanied by computer simulation results and testbed results showing the performance of such BNN solutions.

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UcnPowerNet: Residual learning based clustering and interference coordination in 5G user‐centric networks

Liu

Zhang

2021

Trans Emerging Tel Tech

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In 5th Generation and beyond (5G&B) wireless networks, artificial intelligence can be explored to address problems with uncertain, time‐variant, and complex features. User‐centric network (UCN) can eliminate cell boundaries and reduce interference. And as for the intelligent resource management and interference coordination, the scalability of existing deep learning‐based works degrades greatly as the size of the network increases, which requires more layers to be stacked and causes gradient vanishing problem. In this article, a new deep learning‐based resource management model, UcnPowerNet, is proposed to approximate iterative algorithms for dynamic clustering and interference coordination in complicated UCN, where multiple residual blocks are concatenated with shortcut connections to asymptotically learn the mapping between input and output. Specifically, a cooperative weighted minimum mean square error (WMMSE) algorithm for UCN is carried out in the real domain to generate large near‐optimal training datasets; then we train UcnPowerNet to approximate the output of WMMSE algorithm by minimizing the loss function of mean square error. Moreover, convolutional layer and normalization layer are leveraged to decrease the number of weights and avoid gradients vanishing, respectively. Extensive experiments demonstrate the high approximation accuracy of UcnPowerNet with 94.90% sum‐rate relative to the conventional iterative algorithm while achieving more than 100 speed up.

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A Deep Learning Framework for Optimization of MISO Downlink Beamforming

Cited by 243 publications

References 78 publications

Deep Learning Enabled Optimization of Downlink Beamforming Under Per-Antenna Power Constraints: Algorithms and Experimental Demonstration

Deep Learning Enabled Optimization of Downlink Beamforming Under Per-Antenna Power Constraints: Algorithms and Experimental Demonstration

Model-Driven Beamforming Neural Networks

UcnPowerNet: Residual learning based clustering and interference coordination in 5G user‐centric networks

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