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Deep Reinforcement Learning-Assisted Energy Harvesting Wireless Networks.

Junliang Ye1, Hamid Gharavi1

  • 1The authors are with the National Institute of Standards and Technology, Gaithersburg, MD 20899 USA.

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Summary
This summary is machine-generated.

This study introduces Wolpertinger Deep Deterministic Policy Gradient (W-DDPG) for energy harvesting in heterogeneous ultra-dense networks (HUDN). W-DDPG optimizes energy efficiency and throughput in unpredictable environments.

Keywords:
DDPGReinforcement learningenergy harvestingheterogeneous networkmmWave

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Area of Science:

  • Wireless Communication Networks
  • Energy Harvesting Technologies
  • Machine Learning Applications

Background:

  • Heterogeneous ultra-dense networks (HUDN) face challenges with increasing traffic and power consumption.
  • Energy harvesting in HUDN is crucial but hampered by unpredictable harvested energy levels.
  • Optimizing energy harvesting and data transmission is vital for network performance.

Purpose of the Study:

  • To develop an optimal control strategy for energy harvesting in HUDN.
  • To address the challenge of determining when and where to harvest energy from multiple sources.
  • To enhance both energy efficiency and data throughput in HUDN.

Main Methods:

  • Proposed reinforcement learning methods, specifically Deep Deterministic Policy Gradient (DDPG) and Wolpertinger DDPG (W-DDPG).
  • Utilized W-DDPG to manage large and discrete action spaces for controlling base station operations.
  • Simulated the proposed algorithms in a HUDN environment with energy harvesting.

Main Results:

  • The W-DDPG algorithm demonstrated superior performance compared to the original DDPG and Deep Q-Learning.
  • Achieved significant improvements in both energy efficiency and network throughput.
  • Validated the effectiveness of W-DDPG in managing random energy harvesting.

Conclusions:

  • W-DDPG is an effective approach for optimizing energy harvesting and performance in HUDN.
  • Reinforcement learning, particularly W-DDPG, offers a robust solution for dynamic network control.
  • The proposed method addresses the unpredictability of harvested energy for improved network operation.