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Joint Optimization of Data- and Model-Driven Probing Beams and Beam Predictor

Tianheng Lu, Fan Meng, Zhilei Zhang, Yongming Huang, Cheng Zhang, Xiaoyu Bai

TL;DR

This letter proposes to jointly optimize a data- and model-driven probe beam module and a cascaded data-driven beam predictor, with limitations in that the probe and communicate beams are restricted within the manifold space of uniform planer array and quantization of the phase modulator.

Abstract

Hierarchical search in millimeter-wave (mmWave) communications incurs significant beam training overhead and delay, especially in a dynamic environment. Deep learning-enabled beam prediction is promising to significantly mitigate the overhead and delay, efficiently utilizing the site-specific channel prior. In this work, we propose to jointly optimize a data- and model-driven probe beam module and a cascaded data-driven beam predictor, with limitations in that the probe and communicate beams are restricted within the manifold space of uniform planer array and quantization of the phase modulator. First, The probe beam module senses the mmWave channel with a complex-valued neural network and outputs the counterpart RSRPs of probe beams. Second, the beam predictor estimates the RSRPs in the entire beamspace to minimize the prediction cross entropy and selects the optimal beam with the maximum RSRP value for data transmission. Additionally, we propose to add noise to the phase variables in the probe beam module, against quantization error. Simulation results show the effectiveness of our proposed scheme.

Joint Optimization of Data- and Model-Driven Probing Beams and Beam Predictor

TL;DR

This letter proposes to jointly optimize a data- and model-driven probe beam module and a cascaded data-driven beam predictor, with limitations in that the probe and communicate beams are restricted within the manifold space of uniform planer array and quantization of the phase modulator.

Abstract

Hierarchical search in millimeter-wave (mmWave) communications incurs significant beam training overhead and delay, especially in a dynamic environment. Deep learning-enabled beam prediction is promising to significantly mitigate the overhead and delay, efficiently utilizing the site-specific channel prior. In this work, we propose to jointly optimize a data- and model-driven probe beam module and a cascaded data-driven beam predictor, with limitations in that the probe and communicate beams are restricted within the manifold space of uniform planer array and quantization of the phase modulator. First, The probe beam module senses the mmWave channel with a complex-valued neural network and outputs the counterpart RSRPs of probe beams. Second, the beam predictor estimates the RSRPs in the entire beamspace to minimize the prediction cross entropy and selects the optimal beam with the maximum RSRP value for data transmission. Additionally, we propose to add noise to the phase variables in the probe beam module, against quantization error. Simulation results show the effectiveness of our proposed scheme.
Paper Structure (18 sections, 11 equations, 4 figures, 2 tables, 1 algorithm)

This paper contains 18 sections, 11 equations, 4 figures, 2 tables, 1 algorithm.

Table of Contents

  1. Introduction
  2. Data- and model-driven Probing Beam Training
  3. Beam Domain Equivalent Variables
  4. Noise Adding Technique
  5. System Model and Problem Formulation
  6. System Model
  7. Problem Formulation
  8. Data- and Model-Driven Solution of Probe Beam Training and Beam Predictor
  9. Probe Beam Training
  10. Beam Predictor
  11. Probe Beam Training with Beamspace Variables
  12. Phase Quantization
  13. Simulations
  14. Configurations
  15. Training Convergence Speed
  16. ...and 3 more sections

Figures (4)

  • Figure 1: The illustrative procedure of the proposed scheme.
  • Figure 2: The top-3 prediction accuracy versus training epoch.
  • Figure 3: Top-$K$ beam prediction accuracy for different schemes. In each scheme, from left to right are the original scheme, quantization scheme and noise scheme, respectively.
  • Figure 4: EAR versus MU number.