Ambient Backscatter and Reconfigurable Intelligent Surface Empowered Wireless Communications in Future 6G Networks
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USyd Access
Type
ThesisThesis type
Doctor of PhilosophyAuthor/s
Hu, YunkaiAbstract
In future wireless communication systems, a substantial proportion of devices will be connected to the Internet of Things (IoT) networks for data communications, which poses three critical challenges for designing IoT networks: cost efficiency, spectrum efficiency, and energy ...
See moreIn future wireless communication systems, a substantial proportion of devices will be connected to the Internet of Things (IoT) networks for data communications, which poses three critical challenges for designing IoT networks: cost efficiency, spectrum efficiency, and energy efficiency. Ambient backscatter communication (AmBC), a novel communication scheme that offers low-cost, spectrum-efficient, and energy-efficient data communications, has found itself a competitive solution for developing and deploying future IoT networks. In AmBC systems, the main design challenge is to decode the tag signals from the composite received signals. In this thesis, the author focuses on the transceiver design and performance analysis of the AmBC system by making the following contributions. Firstly, we design a machine learning-based detector to decode the tag signals for an AmBC system. The second focus of this thesis is to study the BER performance of the AmBC systems that utilize the RF source signals with error control coding. The ongoing developments of 5G wireless networks are continuously exposing some inherent limitations. Reconfigurable intelligent surface (RIS), a promising solution to overcome the limitations in current 5G wireless networks and enable the beyond 5G and future sixth-generation (6G) networks, has attracted increasing attention recently. In the third research focus, we investigate the performance of the RIS-assisted wireless system where the signal transmitted from the transmitter is protected by error control codes. We focus on deriving the analytical upper and lower bounds on the bit error probability of the RIS-assisted wireless system with LDPC-coded source signals. We further investigate the performance of the RIS-assisted wireless system with polar codes through simulations. In addition, we show that the deployment of RIS can enhance the system BER performance significantly by increasing the number of RIS reflecting elements.
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See moreIn future wireless communication systems, a substantial proportion of devices will be connected to the Internet of Things (IoT) networks for data communications, which poses three critical challenges for designing IoT networks: cost efficiency, spectrum efficiency, and energy efficiency. Ambient backscatter communication (AmBC), a novel communication scheme that offers low-cost, spectrum-efficient, and energy-efficient data communications, has found itself a competitive solution for developing and deploying future IoT networks. In AmBC systems, the main design challenge is to decode the tag signals from the composite received signals. In this thesis, the author focuses on the transceiver design and performance analysis of the AmBC system by making the following contributions. Firstly, we design a machine learning-based detector to decode the tag signals for an AmBC system. The second focus of this thesis is to study the BER performance of the AmBC systems that utilize the RF source signals with error control coding. The ongoing developments of 5G wireless networks are continuously exposing some inherent limitations. Reconfigurable intelligent surface (RIS), a promising solution to overcome the limitations in current 5G wireless networks and enable the beyond 5G and future sixth-generation (6G) networks, has attracted increasing attention recently. In the third research focus, we investigate the performance of the RIS-assisted wireless system where the signal transmitted from the transmitter is protected by error control codes. We focus on deriving the analytical upper and lower bounds on the bit error probability of the RIS-assisted wireless system with LDPC-coded source signals. We further investigate the performance of the RIS-assisted wireless system with polar codes through simulations. In addition, we show that the deployment of RIS can enhance the system BER performance significantly by increasing the number of RIS reflecting elements.
See less
Date
2021Rights statement
The author retains copyright of this thesis. It may only be used for the purposes of research and study. It must not be used for any other purposes and may not be transmitted or shared with others without prior permission.Faculty/School
Faculty of Engineering, School of Electrical and Information EngineeringAwarding institution
The University of SydneyShare