Your search keyword '"nonlinear EH"' showing total 5 results

1. Energy-Efficient Power Allocation in Non-Linear Energy Harvesting Multiple Relay Systems

Author

Huifang Pan and Qi Zhu

Subjects

SWIPT, multi-relay, nonlinear EH, energy efficiency, power allocation, Industrial engineering. Management engineering, T55.4-60.8, Electronic computers. Computer science, QA75.5-76.95

Abstract

In this paper, to maximize the energy efficiency (EE) in the two-hop multi-relay cooperative decoding and forwarding (DF) system for simultaneous wireless information and power transmission (SWIPT), an optimal power allocation algorithm is proposed, in which the relay energy harvesting (EH) adopts a nonlinear model. Under the constraints, including energy causality, the minimum transmission quality of information and the total transmission power at the relays, an optimization problem is constructed to jointly optimize the transmit power and power-splitting (PS) ratios of multiple relays. Although this problem is a nonlinear fractional programming problem, an iterative algorithm is developed to obtain the optimal power allocation. In particular, the joint power allocation at multiple relays is first decoupled into a single relay power allocation, and then single-relay power allocation is performed by the Dinkelbach iteration algorithm, which can be proven that it is a convex programming problem. Its closed form solutions for different polylines of EH models are obtained by using mathematical methods, such as monotonicity, Lagrange multipliers, the KKT condition and the Cardan formula. The simulation results show the superiority of the power allocation algorithm proposed in this paper in terms of EE.

Published

2021

2. Energy-Efficient Power Allocation in Non-Linear Energy Harvesting Multiple Relay Systems

Author

Qi Zhu and Huifang Pan

Subjects

Mathematical optimization, Karush–Kuhn–Tucker conditions, Optimization problem, Industrial engineering. Management engineering, Computer science, 02 engineering and technology, Data_CODINGANDINFORMATIONTHEORY, T55.4-60.8, Theoretical Computer Science, law.invention, Fractional programming, 0203 mechanical engineering, Relay, law, 0202 electrical engineering, electronic engineering, information engineering, energy efficiency, Computer Science::Information Theory, Numerical Analysis, Power transmission, SWIPT, multi-relay, 020206 networking & telecommunications, 020302 automobile design & engineering, QA75.5-76.95, Transmitter power output, power allocation, Computational Mathematics, Computational Theory and Mathematics, Electronic computers. Computer science, Convex optimization, nonlinear EH, Efficient energy use

Abstract

In this paper, to maximize the energy efficiency (EE) in the two-hop multi-relay cooperative decoding and forwarding (DF) system for simultaneous wireless information and power transmission (SWIPT), an optimal power allocation algorithm is proposed, in which the relay energy harvesting (EH) adopts a nonlinear model. Under the constraints, including energy causality, the minimum transmission quality of information and the total transmission power at the relays, an optimization problem is constructed to jointly optimize the transmit power and power-splitting (PS) ratios of multiple relays. Although this problem is a nonlinear fractional programming problem, an iterative algorithm is developed to obtain the optimal power allocation. In particular, the joint power allocation at multiple relays is first decoupled into a single relay power allocation, and then single-relay power allocation is performed by the Dinkelbach iteration algorithm, which can be proven that it is a convex programming problem. Its closed form solutions for different polylines of EH models are obtained by using mathematical methods, such as monotonicity, Lagrange multipliers, the KKT condition and the Cardan formula. The simulation results show the superiority of the power allocation algorithm proposed in this paper in terms of EE.

Published

2021

3. Energy-Efficient Power Allocation in Non-Linear Energy Harvesting Multiple Relay Systems.

Author

Pan, Huifang, Zhu, Qi, and Billaut, Jean-charles

Subjects

*ENERGY harvesting, *LAGRANGE multiplier, *WIRELESS power transmission, *FRACTIONAL programming, *DECODE & forward communication, *ENERGY consumption, *POWER transmission

Abstract

In this paper, to maximize the energy efficiency (EE) in the two-hop multi-relay cooperative decoding and forwarding (DF) system for simultaneous wireless information and power transmission (SWIPT), an optimal power allocation algorithm is proposed, in which the relay energy harvesting (EH) adopts a nonlinear model. Under the constraints, including energy causality, the minimum transmission quality of information and the total transmission power at the relays, an optimization problem is constructed to jointly optimize the transmit power and power-splitting (PS) ratios of multiple relays. Although this problem is a nonlinear fractional programming problem, an iterative algorithm is developed to obtain the optimal power allocation. In particular, the joint power allocation at multiple relays is first decoupled into a single relay power allocation, and then single-relay power allocation is performed by the Dinkelbach iteration algorithm, which can be proven that it is a convex programming problem. Its closed form solutions for different polylines of EH models are obtained by using mathematical methods, such as monotonicity, Lagrange multipliers, the KKT condition and the Cardan formula. The simulation results show the superiority of the power allocation algorithm proposed in this paper in terms of EE. [ABSTRACT FROM AUTHOR]

Published

2021

4. Outage and Throughput of WPCN-SWIPT Networks with Nonlinear EH Model in Nakagami-m Fading

Author

Ruihong Jiang, Yu Zhang, Zhangdui Zhong, Ke Xiong, Tong Liu, and Li Zhou

Subjects

Computer Networks and Communications, Computer science, lcsh:TK7800-8360, PS, Throughput, 02 engineering and technology, Topology, 0203 mechanical engineering, 0202 electrical engineering, electronic engineering, information engineering, Wireless, Fading, Electrical and Electronic Engineering, Throughput (business), outage probability, business.industry, lcsh:Electronics, SWIPT, 020302 automobile design & engineering, 020206 networking & telecommunications, Nakagami distribution, reliable throughput, Power (physics), Nonlinear system, Hardware and Architecture, Control and Systems Engineering, nonlinear EH, Signal Processing, WPCN, Nakagami-m fading, business

Abstract

This paper analyzes outage probability and reliable throughput performance of a multi-user wireless-powered communication network-simultaneous wireless information and power transfer (WPCN-SWIPT) network with the logistic function-based (LG) nonlinear energy-harvesting (EH) model in Nakagami-m fading. Power-splitting (PS) receiver architecture is considered. The closed-form expressions of the system outage probability and the system reliable throughput are derived, and then the corresponding asymptotic expressions are also provided to achieve simpler calculation in the high-transmit power scenarios. Simulation results demonstrate the correctness of our derived analytical results and show that the systems under the LG nonlinear and linear EH models have very different performance behaviors. Moreover, since the LG nonlinear EH model is closer to the features of practical EH circuit than the linear one, using the LG nonlinear EH model can avoid the false output results of the system performance evaluation.

Published

2019

5. Outage and Throughput of WPCN-SWIPT Networks with Nonlinear EH Model in Nakagami-m Fading.

Author

Jiang, Ruihong, Xiong, Ke, Zhang, Yu, Zhou, Li, Liu, Tong, and Zhong, Zhangdui

Subjects

NAKAGAMI channels, PROBABILITY theory, WIRELESS communications, ENERGY harvesting, ASYMPTOTIC expansions

Abstract

This paper analyzes outage probability and reliable throughput performance of a multi-user wireless-powered communication network-simultaneous wireless information and power transfer (WPCN-SWIPT) network with the logistic function-based (LG) nonlinear energy-harvesting (EH) model in Nakagami-m fading. Power-splitting (PS) receiver architecture is considered. The closed-form expressions of the system outage probability and the system reliable throughput are derived, and then the corresponding asymptotic expressions are also provided to achieve simpler calculation in the high-transmit power scenarios. Simulation results demonstrate the correctness of our derived analytical results and show that the systems under the LG nonlinear and linear EH models have very different performance behaviors. Moreover, since the LG nonlinear EH model is closer to the features of practical EH circuit than the linear one, using the LG nonlinear EH model can avoid the false output results of the system performance evaluation. [ABSTRACT FROM AUTHOR]

Published

2019