Distributed Power Control for Large Energy Harvesting Networks: A Multi-Agent Deep Reinforcement Learning Approach

Sharma, Maya; Zappone, Alessio; Assaad, Mohamad; Debbah, Mérouane; Vassilaras, Spyridon

doi:10.1109/tccn.2019.2949589

Cited by 44 publications

(23 citation statements)

References 36 publications

(70 reference statements)

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“…That said, such a combination of environment nonstationarity and partial observability makes learning extremely difficult, which is made even worse if we scale the number of users large as in the upcoming internet of things era. While there have been some recent works [91] that attempt to solve the issue and establish the convergence guarantee of mean-field multi-agent RL, more investigation in this direction is still desired.…”

Section: Multi-agent Consideration In Deep Rlmentioning

confidence: 99%

Deep-Learning-Based Wireless Resource Allocation With Application to Vehicular Networks

et al. 2020

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It has been a long-held belief that judicious resource allocation is critical to mitigating interference, improving network efficiency, and ultimately optimizing wireless communication performance. The traditional wisdom is to explicitly formulate resource allocation as an optimization problem and then exploit mathematical programming to solve the problem to a certain level of optimality. Nonetheless, as wireless networks become increasingly diverse and complex, e.g., in the highmobility vehicular networks, the current design methodologies face significant challenges and thus call for rethinking of the traditional design philosophy. Meanwhile, deep learning, with many success stories in various disciplines, represents a promising alternative due to its remarkable power to leverage data for problem solving. In this paper, we discuss the key motivations and roadblocks of using deep learning for wireless resource allocation with application to vehicular networks. We review major recent studies that mobilize the deep learning philosophy in wireless resource allocation and achieve impressive results. We first discuss deep learning assisted optimization for resource allocation. We then highlight the deep reinforcement learning approach to address resource allocation problems that are difficult to handle in the traditional optimization framework. We also identify some research directions that deserve further investigation.

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Section: Multi-agent Consideration In Deep Rlmentioning

confidence: 99%

Deep-Learning-Based Wireless Resource Allocation With Application to Vehicular Networks

et al. 2020

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“…In [115], a multi-agent DRL-based framework was proposed for power control and maximization of throughput in energy-harvesting super IoT systems. Furthermore, a DNN based for distributed online power control is developed to study the policies in the system.…”

Section: Energy Consumption/harvestingmentioning

confidence: 99%

Machine Learning in Beyond 5G/6G Networks—State-of-the-Art and Future Trends

et al. 2021

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Artificial Intelligence (AI) and especially Machine Learning (ML) can play a very important role in realizing and optimizing 6G network applications. In this paper, we present a brief summary of ML methods, as well as an up-to-date review of ML approaches in 6G wireless communication systems. These methods include supervised, unsupervised and reinforcement techniques. Additionally, we discuss open issues in the field of ML for 6G networks and wireless communications in general, as well as some potential future trends to motivate further research into this area.

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“…In [28], the authors proposed a novel energy management algorithm to maximize the packet rate for point-to-point communication based on the actor-critic RL framework. In [29], a distributed multi-agent RL algorithm is proposed based on an identical reward function for all nodes.…”

Section: A Related Work and Contributionmentioning

confidence: 99%

“…Update θ (i) t and η (i) t using ( 28) and (29) t+1 has an associated potential function R t+1 (the centralized RL algorithm reward function) based on the potential games framework [41], [42]. Therefore, the optimization of the individual reward functions leads to a local optimal of the potential function under certain conditions.…”

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confidence: 99%

Reinforcement Learning Framework for Delay Sensitive Energy Harvesting Wireless Sensor Networks

Al-Tous

Barhumi

2021

IEEE Sensors J.

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A multi-hop energy harvesting wireless sensor network (EH-WSNs) is a key enabler for future communication systems such as the internet-of-things. Optimal power management and routing selection are important for the operation and successful deployment of EH-WSNs. Characterizing the optimal policies increases significantly with the number of nodes in the network. In this paper, optimal control policy is devised based on minimum-delay transmission in a multi-hop EH-WSN using reinforcement learning (RL). The WSN consists of M EH sensor nodes aiming to transmit their data to a sink node with a minimum delay. Each sensor node is equipped with a battery of limited capacity to save the harvested energy and a data buffer of limited size to store both the sensed and relayed data from neighboring nodes. Centralized and distributed RL algorithms are considered for EH-WSNs. In the centralized RL algorithm the control action is taken at a central unit using the state information of all sensor nodes. In the distributed RL algorithm the control action is taken locally at each sensor node using its state of information and the state information of neighboring nodes. The proposed RL algorithms are based on the state-action-reward-state-action (SARSA) algorithm. Simulation results demonstrate the merits of the proposed algorithms.

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Distributed Power Control for Large Energy Harvesting Networks: A Multi-Agent Deep Reinforcement Learning Approach

Cited by 44 publications

References 36 publications

Deep-Learning-Based Wireless Resource Allocation With Application to Vehicular Networks

Deep-Learning-Based Wireless Resource Allocation With Application to Vehicular Networks

Machine Learning in Beyond 5G/6G Networks—State-of-the-Art and Future Trends

Reinforcement Learning Framework for Delay Sensitive Energy Harvesting Wireless Sensor Networks

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