Toward Optimal Power Control and Transfer for Energy Harvesting Amplify-and-Forward Relay Networks

Singh, Keshav; Ku, Meng‐Lin; Lin, Jia-Chin; Ratnarajah, Tharmalingam

doi:10.1109/twc.2018.2834528

Cited by 40 publications

(19 citation statements)

References 53 publications

(107 reference statements)

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“…where P max is the source transmission power budget. 2 Further, constraint (C.1) and (C.2) ensure that each subcarrier in MA phase is paired with a subcarrier in the BC phase, (C.3) and (C.4) establish that each paired subcarrier is allocated to one-and-only-one user pair and relay node respectively, (C.5) mandates that the energy utilisation by relay nodes never exceed their harvested energy, and (C.6) bounds the network's transmit power regulation.…”

Section: Problem Formulation and Transformationmentioning

confidence: 99%

“…Therefore, to meet these requirements it is currently projected that by the end of 2030, there will be about 4 Gt (Gigatonnes) of CO 2 emissions by the information and communication (ICT) sector [1]. To achieve the greentarget for the environment, one effective way is to harvest energy from the ambient sources like solar, wind etc [2], [3] or radio-frequency (RF) signals. Another way is to design cellular networks with greater scrutiny towards energy-aware engineering and resource allocation policies that not only prolong the network's lifespan, but also contribute towards energy savings under the protection of green communications [1].…”

Section: Introductionmentioning

confidence: 99%

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Time-Switching EH-Based Joint Relay Selection and Resource Allocation Algorithms for Multi-User Multi-Carrier AF Relay Networks

Gupta

Singh

Sellathurai

2019

IEEE Trans. on Green Commun. Netw.

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In this paper, an energy efficiency maximization (EEM) optimization problem for the multiuser multicarrier energy-constrained amplify-and-forward (AF) multi-relay network is formulated under the total source transmit power budget and energy-causality constraints. We consider that each relay node is solely powered by the source nodes, employing energy harvesting time-switching (EHTS) protocol to harvest the energy through the ambient radio-frequency (RF) signal transmitted from the source nodes under the simultaneous wireless information and power transfer (SWIPT) paradigm. First, we propose a subcarrier and energy causality-based multi-relay selection policy. Second, we jointly optimize the parameters that control the energy efficiency (EE) of the system namely multi-relay selection, subcarrier pairing, user allocation, power allocation, and RF EHTS time block, that renders the problem to be a mixed integer non-linear programming problem (MINLP) which remains NP-hard to solve. Hence, we remodel the problem to a tractable quasi-concave form by applying a string of convex transformations. Later, we propose an iterative EEM algorithm to optimize the multi-parameter problem. Further, a suboptimal and best relay selection algorithm is studied by trading-off between complexity and performance. The effectiveness of the proposed algorithms is demonstrated by simulation results.

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Section: Problem Formulation and Transformationmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Time-Switching EH-Based Joint Relay Selection and Resource Allocation Algorithms for Multi-User Multi-Carrier AF Relay Networks

Gupta

Singh

Sellathurai

2019

IEEE Trans. on Green Commun. Netw.

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“…The strategy is a joint power control and energy transfer scheme to maximize the throughput by considering the energy causality constraints. In [33], an AF-RN with energy harvesting (EH) source and relay nodes is investigated. To consider the energy arrival profiles and the energy cooperation between EH nodes, a joint power control and transfer is designed to maximize the total data rate, subject to energy causality and battery storage constraints.…”

Section: Wireless Power Transfermentioning

confidence: 99%

Joint Balanced Routing and Energy Harvesting Strategy for Maximizing Network Lifetime in WSNs

Tala't

Chiu

et al. 2019

Energies

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Nowadays, wireless sensor networks (WSNs) are becoming increasingly popular due to the wide variety of applications. The network can be utilized to collect and transmit numerous types of messages to a data sink in a many-to-one fashion. The WSNs usually contain sensors with low communication ability and limited battery power, and the battery replacement is difficult in WSNs for large amount embedded nodes, which indicates a balanced routing strategy is essential to be developed for an extensive operation lifecycle. To realize the goal, the research challenges require not only to minimize the energy consumption in each node but also to balance the whole WSNs traffic load. In this article, a Shortest Path Tree with Energy Balance Routing strategy (SPT-EBR) based on a forward awareness factor is proposed. In SPT-EBR, Two methods are presented including the power consumption and the energy harvesting schemes to select the forwarding node according to the awareness factors of link weight. First, the packet forwarding rate factor is considered in the power consumption scheme to update the link weight for the sensors with higher power consumption and mitigate the traffic load of hotspot nodes to achieve the energy balance network. With the assistance of the power consumption scheme, hotspot nodes can be transferred from the irregular location to the same intra-layer from the sink. Based on this feature, the energy harvesting scheme combines both the packet forwarding rate and the power charging rate factors together to update the link weight with a new battery charging rate factor for hotspot nodes. Finally, simulation results validate that both power consumption and energy harvesting schemes in SPT-EBR achieve better energy balance performance and save more charging power than the conventional shortest path algorithm and thus improve the overall network lifecycle.

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“…Indeed, even in the standard Gaussian relay channel, which is not impaired by multi-user interference, both DF and CF schemes achieve large rates than AF [16]. Second, AF relaying in multi-user networks has been investigated mostly in the multi-hop special case, in which the direct link between the user and its destination is negligible [17], [18], [19], [20], [21], [22], [23], [24], [25]. When the direct link is taken into account, as in our work, AF turns the channel into a channel with memory [16], under which the achievable rate regions have very complex expressions [26], [27] leading to highly non trivial optimization problems.…”

Section: Introductionmentioning

confidence: 99%

Full-Duplex Relaying for Opportunistic Spectrum Access Under an Overall Power Constraint

Savard

Belmega

2020

IEEE Access

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To meet the bold requirements of future generation networks, emerging technologies such as opportunistic spectrum access, multi-tier networks, full-duplexing and cooperative networks have to be exploited. In this paper, we propose to blend all the above and globally optimize a relay-aided cognitive radio network composed of a licensed link and an opportunistic link, which is helped by a full-duplex relay node. The opportunistic transmission is allowed provided that a minimum Quality of Service (QoS) constraint is met at the licensed user. First, we derive the achievable rate region under two relaying schemes, namely Decode-and-Forward (DF) and Compress-and-Forward (CF). Then we investigate the optimal power allocation policies for the opportunistic user and the relay under an overall power constraint. The resulting optimization problems are non-convex programs because of the non-trivial operations at the relay (for both CF and DF) and, for DF relaying, the non-convex QoS constraint. Remarkably, the optimal solution is stated in closed-form for CF, whereas it is obtained numerically for DF. Finally, we evaluate numerically the network performance under the two relaying schemes. It turns out that DF outperforms CF only when the relay is close to the opportunistic transmitter and that CF relaying is always useful. INDEX TERMS Full-duplex relaying, opportunistic spectrum access, optimal power allocation

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Toward Optimal Power Control and Transfer for Energy Harvesting Amplify-and-Forward Relay Networks

Cited by 40 publications

References 53 publications

Time-Switching EH-Based Joint Relay Selection and Resource Allocation Algorithms for Multi-User Multi-Carrier AF Relay Networks

Time-Switching EH-Based Joint Relay Selection and Resource Allocation Algorithms for Multi-User Multi-Carrier AF Relay Networks

Joint Balanced Routing and Energy Harvesting Strategy for Maximizing Network Lifetime in WSNs

Full-Duplex Relaying for Opportunistic Spectrum Access Under an Overall Power Constraint

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