Energy Provision Minimization in Wireless Powered Communication Networks With Network Throughput Demand: TDMA or NOMA?

Recently, the newly emerging wireless powered communication network (WPCN) has drawn significant interests, where the network nodes are powered by the energy harvested from the radio-frequency (RF) signal. This paper focuses on the widely studied WPCN, where one hybrid sink (H-sink) coordinates the...

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Bibliographic Details
Published in:IEEE transactions on communications 2019-09, Vol.67 (9), p.6401-6414
Main Authors: Chi, Kaikai, Chen, Zhebiao, Zheng, Kechen, Zhu, Yi-hua, Liu, Jiajia
Format: Article
Language:English
Subjects:
Algorithms
Circuits
Communication networks
Computer simulation
Energy conservation
Energy consumption
energy efficiency
Energy transfer
Energy transmission
Minimization
network throughput
Nodes
NOMA
Nonorthogonal multiple access
Optimization
Power consumption
Protocol (computers)
Radio frequency
Radio signals
Resource management
TDMA
Throughput
Time Division Multiple Access
Wireless communication
Wireless communications
Wireless networks
Wireless powered communication networks
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Summary:Recently, the newly emerging wireless powered communication network (WPCN) has drawn significant interests, where the network nodes are powered by the energy harvested from the radio-frequency (RF) signal. This paper focuses on the widely studied WPCN, where one hybrid sink (H-sink) coordinates the wireless energy/information transmissions to/from a set of one-hop nodes powered by the harvested RF energy only, and aims to minimize the network-throughput constrained H-sink's energy provision (EP). Specifically, we investigate the performance of two important MAC protocols: time-division multiple access (TDMA) and non-orthogonal multiple access (NOMA). For both the TDMA-based WPCN (T-WPCN) and NOMA-based WPCN (N-WPCN), we first formulate the EP minimization problems as the non-linear optimization problems, then transform them into convex problems, and finally propose an efficient algorithm, which jointly uses the golden-section search and bisection search methods to determine the optimal time allocation of H-sink's energy transfer and each node's information transmission as well as the optimal H-sink's transmit power. Furthermore, for the scenarios where the circuit power is negligible, we first prove that the optimal H-sink's transmit power is the maximum allowable value, then prove theoretically that the NOMA and TDMA achieve the same EP, and also present a more efficient algorithm for the EP minimization problem. Simulation results demonstrate that the TDMA outperforms NOMA when the circuit power is non-negligible because the circuit energy consumption of NOMA accounts for a large percentage of the total energy consumption.
ISSN:0090-6778
1558-0857
DOI:10.1109/TCOMM.2019.2921584