Optimal Resource Allocation in Wireless Powered Relay Networks with Nonlinear Energy Harvesters

Qi Gu; Gongpu Wang; Rongfei Fan; Ning Zhang; Hai Jiang; Zhangdui Zhong

doi:10.1109/LWC.2019.2955696

Optimal Resource Allocation in Wireless Powered Relay Networks with Nonlinear Energy Harvesters

Qi Gu, Gongpu Wang^*, Rongfei Fan, Ning Zhang, Hai Jiang, Zhangdui Zhong

^*Corresponding author for this work

School of Cyberspace Science and Technology

Research output: Contribution to journal › Article › peer-review

10 Citations (Scopus)

Abstract

This letter investigates a multiple-relay decode-and-forward (DF) network with simultaneous wireless information and power transfer (SWIPT). The relays use the power splitting (PS) technique to receive radio frequency (RF) energy and information simultaneously from the source. To characterize nonlinearity of energy harvesters at the relays, two existing models are adopted, which are the logistic function model and the constant-linear-constant (CLC) model. We target end-to-end throughput maximization by optimizing the power and bandwidth assignment for every source-relay-destination link and the PS ratio at every relay node. The formulated problems are demonstrated to be nonconvex. Through a series of analysis and transformations, we find global optimal solutions for the formulated problems. Numerical results verify the effectiveness of our proposed methods.

Original language	English
Article number	8913468
Pages (from-to)	371-375
Number of pages	5
Journal	IEEE Wireless Communications Letters
Volume	9
Issue number	3
DOIs	https://doi.org/10.1109/LWC.2019.2955696
Publication status	Published - Mar 2020

Keywords

Simultaneous wireless information and power transfer (SWIPT)
multiple relays
nonlinear energy harvesting model
throughput maximization

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10.1109/LWC.2019.2955696

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title = "Optimal Resource Allocation in Wireless Powered Relay Networks with Nonlinear Energy Harvesters",

abstract = "This letter investigates a multiple-relay decode-and-forward (DF) network with simultaneous wireless information and power transfer (SWIPT). The relays use the power splitting (PS) technique to receive radio frequency (RF) energy and information simultaneously from the source. To characterize nonlinearity of energy harvesters at the relays, two existing models are adopted, which are the logistic function model and the constant-linear-constant (CLC) model. We target end-to-end throughput maximization by optimizing the power and bandwidth assignment for every source-relay-destination link and the PS ratio at every relay node. The formulated problems are demonstrated to be nonconvex. Through a series of analysis and transformations, we find global optimal solutions for the formulated problems. Numerical results verify the effectiveness of our proposed methods.",

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author = "Qi Gu and Gongpu Wang and Rongfei Fan and Ning Zhang and Hai Jiang and Zhangdui Zhong",

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T1 - Optimal Resource Allocation in Wireless Powered Relay Networks with Nonlinear Energy Harvesters

AU - Gu, Qi

AU - Wang, Gongpu

AU - Fan, Rongfei

AU - Zhang, Ning

AU - Jiang, Hai

AU - Zhong, Zhangdui

PY - 2020/3

Y1 - 2020/3

N2 - This letter investigates a multiple-relay decode-and-forward (DF) network with simultaneous wireless information and power transfer (SWIPT). The relays use the power splitting (PS) technique to receive radio frequency (RF) energy and information simultaneously from the source. To characterize nonlinearity of energy harvesters at the relays, two existing models are adopted, which are the logistic function model and the constant-linear-constant (CLC) model. We target end-to-end throughput maximization by optimizing the power and bandwidth assignment for every source-relay-destination link and the PS ratio at every relay node. The formulated problems are demonstrated to be nonconvex. Through a series of analysis and transformations, we find global optimal solutions for the formulated problems. Numerical results verify the effectiveness of our proposed methods.

AB - This letter investigates a multiple-relay decode-and-forward (DF) network with simultaneous wireless information and power transfer (SWIPT). The relays use the power splitting (PS) technique to receive radio frequency (RF) energy and information simultaneously from the source. To characterize nonlinearity of energy harvesters at the relays, two existing models are adopted, which are the logistic function model and the constant-linear-constant (CLC) model. We target end-to-end throughput maximization by optimizing the power and bandwidth assignment for every source-relay-destination link and the PS ratio at every relay node. The formulated problems are demonstrated to be nonconvex. Through a series of analysis and transformations, we find global optimal solutions for the formulated problems. Numerical results verify the effectiveness of our proposed methods.

KW - Simultaneous wireless information and power transfer (SWIPT)

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KW - nonlinear energy harvesting model

KW - throughput maximization

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Optimal Resource Allocation in Wireless Powered Relay Networks with Nonlinear Energy Harvesters

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