Energy-Efficient Power Allocation and Joint User Association in Multiuser-Downlink Massive MIMO System

Salh, Adeeb; Shah, Nor Shahida Mohd; Audah, Lukman; Abdullah, Qazwan; Jabbar, Waheb A.; Mohamad, Mahathir bin

doi:10.1109/access.2019.2958640

Cited by 33 publications

(19 citation statements)

References 40 publications

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“…Furthermore, the authors in [18] investigate the downlink EE optimization problem by jointly performing power allocation and user association, while also considering the minimum sum-rate constraints and the maximum power constraints for the transmitters. An energy-efficient lowcomplexity algorithm is thus developed and implemented on a downlink massive MIMO system to jointly allocate the optimal transmission power using Newton's methods and configure the user association scheme based on the Lagrange's decomposition methods, ensuring high minimal sum-rate constraints.…”

Section: Related Workmentioning

confidence: 99%

Deep Reinforcement Learning for Energy-Efficient Multi-Channel Transmissions in 5G Cognitive HetNets: Centralized, Decentralized and Transfer Learning Based Solutions

Giannopoulos¹,

Spantideas

Kapsalis

et al. 2021

IEEE Access

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Energy efficiency (EE) constitutes a key target in the deployment of 5G networks, especially due to the increased densification and heterogeneity. In this paper, a Deep Q-Network (DQN) based power control scheme is proposed for improving the system-level EE of two-tier 5G heterogeneous and multichannel cells. The algorithm aims to maximize the EE of the system by regulating the transmission power of the downlink channels and reconfiguring the user association scheme. To efficiently solve the EE problem, a DQN-based method is established, properly modified to ensure adequate QoS of each user (via defining a demand-driven rewarding system) and near-optimal power adjustment in each transmission link. To directly compare different DQN-based approaches, a centralized (C-DQN), a multi-agent (MA-DQN) and a transfer learning-based (T-DQN) method are deployed to address whether their applicability is beneficial in the 5G HetNets. Results confirmed that DQN-assisted actions could offer enhanced network-wide EE performance, as they balance the trade-off between the power consumption and achieved throughput (in Mbps/Watt). Excessive performance was observed for the MA-DQN approach (>5 Mbps/Watt), since the decentralized learning supports low-dimensional agents to be coordinated with each other through global rewards. In further comparing the T-DQN against MA-DQN solutions, T-DQN presents beneficial usage for very low or very high inter-cell distances, whereas the usage of MA-DQN is preferred (by a factor of ~1.3) for intermediate inter-cell distances (100-600m), where the power savings are feasible towards achieving increased EE. Furthermore, T-DQN scheme guarantees good EE solutions (above 2 Mbps/Watt), even for densely-deployed macro-cells, with effortless training and memory requirements. On the contrary, MA-DQN offers the best EE solutions at the expense of massive training resources and required training time.

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Section: Related Workmentioning

confidence: 99%

Deep Reinforcement Learning for Energy-Efficient Multi-Channel Transmissions in 5G Cognitive HetNets: Centralized, Decentralized and Transfer Learning Based Solutions

Giannopoulos¹,

Spantideas

Kapsalis

et al. 2021

IEEE Access

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“…The companies of VPP project and response to electricity demand are presented below, see Table 7. In this way, Smart City can reduce energy consumption, and can also increase energy efficiency with the use of renewable energy and thus reduce energy costs for users, according to the authors of [38]. Also, small users in future power systems will have more DERs, energy storage batteries and flexible loads, which will be based on ubiquitous 5G and IoT networks, according to [5].…”

Section: G Iotmentioning

confidence: 99%

Review of Methods to Reduce Energy Consumption in A Smart City Based On IoT and 5G Technology

et al. 2021

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The evolution of the technology 5G has influenced the Internet of the Things (IoT) according to the wireless communications of minor latency, and major speed compared to the existing technologies. Consequently, from the 21st century, 5G will act as the spinal column of the IoT and will level the way for the design and deployment of a Smart City, nevertheless, this progress has a negative point which is demonstrated in the energy consumption. The target of this investigation is to announce methods to reduce the consumption of energy in one Smart City based on the IoT and the technology 5G. The results obtained in this investigation allow determining that 5G and the IoT will have a major energy consumption with about 80 % of the entire potency, due to the transmission and reception of a big quantity of information in a Smart City. Likewise, this research, contributes to the knowledge, presenting a review of methods that allow minimizing energy consumption and projects that improve energy efficiency.

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“…A low‐complexity algorithm is proposed using the Newton methods and common user communication based on the Lagrange analysis method. The simulation results of this paper show that the proposed algorithm provides maximum energy efficiency for the case where the base station has a large number of transmitter antennas 6 . The total rate gain obtained from the PA method in a multicellular massive MIMO system is used in Zhang et al 7 The transmission in this system is duplex time transfer, and a scheduling PA method is proposed that prevents joint optimization with high complexity in the system 7 .…”

Section: Introductionmentioning

confidence: 99%

Secure energy efficient power allocation in massive multiple‐input multiple‐output systems with an eavesdropper using cell division technique

Gharagezlou

Pourrostam

Nangir

2021

Int J Communication

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Summary In this paper, we study energy‐efficient power allocation (PA) to secure the confidential information of massive multiple‐input multiple‐output (MIMO) systems in the presence of an eavesdropper. First a training scheme is presented in the uplink using the MMSE method. Based on the estimated channel state information (CSI), the base station (BS) encrypts the confidential information. Next, the ergodic secret rate is obtained at the downlink. In this paper, in order to maximize the ergodic secrecy rate, the allocation of common power in the uplink and downlink is proposed by considering the constraints such as the transmit power constraint in the uplink, the transmit power constraint in the downlink, and the minimum ergodic secret rate constraint. The objective function in the proposed scenario is a nonconvex problem, which first becomes a convex problem and then, by using the Lagrange dual function method, the problem becomes an unconstraint problem. We also divide the cell into two areas using the cell division method. A practical energy‐efficient PA algorithm is presented which deals with the adverse effect of the eavesdropper. Simulations are carried out to demonstrate the effectiveness of the proposed methods.

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Energy-Efficient Power Allocation and Joint User Association in Multiuser-Downlink Massive MIMO System

Cited by 33 publications

References 40 publications

Deep Reinforcement Learning for Energy-Efficient Multi-Channel Transmissions in 5G Cognitive HetNets: Centralized, Decentralized and Transfer Learning Based Solutions

Deep Reinforcement Learning for Energy-Efficient Multi-Channel Transmissions in 5G Cognitive HetNets: Centralized, Decentralized and Transfer Learning Based Solutions

Review of Methods to Reduce Energy Consumption in A Smart City Based On IoT and 5G Technology

Secure energy efficient power allocation in massive multiple‐input multiple‐output systems with an eavesdropper using cell division technique

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