The Experts below are selected from a list of 173661 Experts worldwide ranked by ideXlab platform
Qingwen Liu - One of the best experts on this subject based on the ideXlab platform.
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wireless energy Transmission Channel modeling in resonant beam charging for iot devices
IEEE Internet of Things Journal, 2019Co-Authors: Wei Wang, Qingqing Zhang, Hua Lin, Mingqing Liu, Xiaoyan Liang, Qingwen LiuAbstract:Power supply for Internet of Things (IoT) devices is one of the bottlenecks in IoT development. To provide perpetual power supply for IoT devices, resonant beam charging (RBC) is a promising safe, long-range, and high-power wireless power transfer solution. How long distance RBC can reach and how much power RBC can transfer? In this paper, we analyze the consistent and steady operational conditions of the RBC system, which determine the maximum power Transmission distance. Then, we study the power Transmission efficiency within the operational distance, which determines the deliverable power through the RBC energy Transmission Channel. Based on the theoretical model of the wireless energy Transmission Channel, we establish a testbed. According to the experimental measurement, we validate our theoretical model. The experiments verify that the output electrical power at the RBC receiver can be up to 2 W. The maximum energy Transmission distance is 2.6 m. Both the experimental and theoretical performance of the RBC system are evaluated in terms of the Transmission distance, the Transmission efficiency, and the output electrical power. Our theoretical model and experimental testbed lead to the guidelines for the RBC system design and implementation in practice.
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wireless energy Transmission Channel modeling in resonant beam charging for iot devices
arXiv: Signal Processing, 2018Co-Authors: Wei Wang, Qingqing Zhang, Hua Lin, Mingqing Liu, Xiaoyan Liang, Qingwen LiuAbstract:Power supply for Internet of Things (IoT) devices is one of the bottlenecks in IoT development. To provide perpetual power supply to IoT devices, resonant beam charging (RBC) is a promising safe, long-range and high-power wireless power transfer solution. How long distance can RBC reach and how much power can RBC transfer? In this paper, we analyze the RBC's consistent and steady operational conditions, which determine the maximum power Transmission distance. Moreover, we study the power Transmission efficiency within the operational distance, which determines the deliverable power through the RBC energy Transmission Channel. Based on this energy Transmission Channel modeling, we numerically evaluate its impacts on the RBC system performance in terms of the Transmission distance, the Transmission efficiency, and the output electrical power. The analysis leads to the guidelines for the RBC system design and implementation, which can deliver multi-Watt power over multi-meter distance wirelessly for IoT devices.
Wei Wang - One of the best experts on this subject based on the ideXlab platform.
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wireless energy Transmission Channel modeling in resonant beam charging for iot devices
IEEE Internet of Things Journal, 2019Co-Authors: Wei Wang, Qingqing Zhang, Hua Lin, Mingqing Liu, Xiaoyan Liang, Qingwen LiuAbstract:Power supply for Internet of Things (IoT) devices is one of the bottlenecks in IoT development. To provide perpetual power supply for IoT devices, resonant beam charging (RBC) is a promising safe, long-range, and high-power wireless power transfer solution. How long distance RBC can reach and how much power RBC can transfer? In this paper, we analyze the consistent and steady operational conditions of the RBC system, which determine the maximum power Transmission distance. Then, we study the power Transmission efficiency within the operational distance, which determines the deliverable power through the RBC energy Transmission Channel. Based on the theoretical model of the wireless energy Transmission Channel, we establish a testbed. According to the experimental measurement, we validate our theoretical model. The experiments verify that the output electrical power at the RBC receiver can be up to 2 W. The maximum energy Transmission distance is 2.6 m. Both the experimental and theoretical performance of the RBC system are evaluated in terms of the Transmission distance, the Transmission efficiency, and the output electrical power. Our theoretical model and experimental testbed lead to the guidelines for the RBC system design and implementation in practice.
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wireless energy Transmission Channel modeling in resonant beam charging for iot devices
arXiv: Signal Processing, 2018Co-Authors: Wei Wang, Qingqing Zhang, Hua Lin, Mingqing Liu, Xiaoyan Liang, Qingwen LiuAbstract:Power supply for Internet of Things (IoT) devices is one of the bottlenecks in IoT development. To provide perpetual power supply to IoT devices, resonant beam charging (RBC) is a promising safe, long-range and high-power wireless power transfer solution. How long distance can RBC reach and how much power can RBC transfer? In this paper, we analyze the RBC's consistent and steady operational conditions, which determine the maximum power Transmission distance. Moreover, we study the power Transmission efficiency within the operational distance, which determines the deliverable power through the RBC energy Transmission Channel. Based on this energy Transmission Channel modeling, we numerically evaluate its impacts on the RBC system performance in terms of the Transmission distance, the Transmission efficiency, and the output electrical power. The analysis leads to the guidelines for the RBC system design and implementation, which can deliver multi-Watt power over multi-meter distance wirelessly for IoT devices.
Xiaoyan Liang - One of the best experts on this subject based on the ideXlab platform.
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wireless energy Transmission Channel modeling in resonant beam charging for iot devices
IEEE Internet of Things Journal, 2019Co-Authors: Wei Wang, Qingqing Zhang, Hua Lin, Mingqing Liu, Xiaoyan Liang, Qingwen LiuAbstract:Power supply for Internet of Things (IoT) devices is one of the bottlenecks in IoT development. To provide perpetual power supply for IoT devices, resonant beam charging (RBC) is a promising safe, long-range, and high-power wireless power transfer solution. How long distance RBC can reach and how much power RBC can transfer? In this paper, we analyze the consistent and steady operational conditions of the RBC system, which determine the maximum power Transmission distance. Then, we study the power Transmission efficiency within the operational distance, which determines the deliverable power through the RBC energy Transmission Channel. Based on the theoretical model of the wireless energy Transmission Channel, we establish a testbed. According to the experimental measurement, we validate our theoretical model. The experiments verify that the output electrical power at the RBC receiver can be up to 2 W. The maximum energy Transmission distance is 2.6 m. Both the experimental and theoretical performance of the RBC system are evaluated in terms of the Transmission distance, the Transmission efficiency, and the output electrical power. Our theoretical model and experimental testbed lead to the guidelines for the RBC system design and implementation in practice.
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wireless energy Transmission Channel modeling in resonant beam charging for iot devices
arXiv: Signal Processing, 2018Co-Authors: Wei Wang, Qingqing Zhang, Hua Lin, Mingqing Liu, Xiaoyan Liang, Qingwen LiuAbstract:Power supply for Internet of Things (IoT) devices is one of the bottlenecks in IoT development. To provide perpetual power supply to IoT devices, resonant beam charging (RBC) is a promising safe, long-range and high-power wireless power transfer solution. How long distance can RBC reach and how much power can RBC transfer? In this paper, we analyze the RBC's consistent and steady operational conditions, which determine the maximum power Transmission distance. Moreover, we study the power Transmission efficiency within the operational distance, which determines the deliverable power through the RBC energy Transmission Channel. Based on this energy Transmission Channel modeling, we numerically evaluate its impacts on the RBC system performance in terms of the Transmission distance, the Transmission efficiency, and the output electrical power. The analysis leads to the guidelines for the RBC system design and implementation, which can deliver multi-Watt power over multi-meter distance wirelessly for IoT devices.
Qingqing Zhang - One of the best experts on this subject based on the ideXlab platform.
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wireless energy Transmission Channel modeling in resonant beam charging for iot devices
IEEE Internet of Things Journal, 2019Co-Authors: Wei Wang, Qingqing Zhang, Hua Lin, Mingqing Liu, Xiaoyan Liang, Qingwen LiuAbstract:Power supply for Internet of Things (IoT) devices is one of the bottlenecks in IoT development. To provide perpetual power supply for IoT devices, resonant beam charging (RBC) is a promising safe, long-range, and high-power wireless power transfer solution. How long distance RBC can reach and how much power RBC can transfer? In this paper, we analyze the consistent and steady operational conditions of the RBC system, which determine the maximum power Transmission distance. Then, we study the power Transmission efficiency within the operational distance, which determines the deliverable power through the RBC energy Transmission Channel. Based on the theoretical model of the wireless energy Transmission Channel, we establish a testbed. According to the experimental measurement, we validate our theoretical model. The experiments verify that the output electrical power at the RBC receiver can be up to 2 W. The maximum energy Transmission distance is 2.6 m. Both the experimental and theoretical performance of the RBC system are evaluated in terms of the Transmission distance, the Transmission efficiency, and the output electrical power. Our theoretical model and experimental testbed lead to the guidelines for the RBC system design and implementation in practice.
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wireless energy Transmission Channel modeling in resonant beam charging for iot devices
arXiv: Signal Processing, 2018Co-Authors: Wei Wang, Qingqing Zhang, Hua Lin, Mingqing Liu, Xiaoyan Liang, Qingwen LiuAbstract:Power supply for Internet of Things (IoT) devices is one of the bottlenecks in IoT development. To provide perpetual power supply to IoT devices, resonant beam charging (RBC) is a promising safe, long-range and high-power wireless power transfer solution. How long distance can RBC reach and how much power can RBC transfer? In this paper, we analyze the RBC's consistent and steady operational conditions, which determine the maximum power Transmission distance. Moreover, we study the power Transmission efficiency within the operational distance, which determines the deliverable power through the RBC energy Transmission Channel. Based on this energy Transmission Channel modeling, we numerically evaluate its impacts on the RBC system performance in terms of the Transmission distance, the Transmission efficiency, and the output electrical power. The analysis leads to the guidelines for the RBC system design and implementation, which can deliver multi-Watt power over multi-meter distance wirelessly for IoT devices.
Hua Lin - One of the best experts on this subject based on the ideXlab platform.
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wireless energy Transmission Channel modeling in resonant beam charging for iot devices
IEEE Internet of Things Journal, 2019Co-Authors: Wei Wang, Qingqing Zhang, Hua Lin, Mingqing Liu, Xiaoyan Liang, Qingwen LiuAbstract:Power supply for Internet of Things (IoT) devices is one of the bottlenecks in IoT development. To provide perpetual power supply for IoT devices, resonant beam charging (RBC) is a promising safe, long-range, and high-power wireless power transfer solution. How long distance RBC can reach and how much power RBC can transfer? In this paper, we analyze the consistent and steady operational conditions of the RBC system, which determine the maximum power Transmission distance. Then, we study the power Transmission efficiency within the operational distance, which determines the deliverable power through the RBC energy Transmission Channel. Based on the theoretical model of the wireless energy Transmission Channel, we establish a testbed. According to the experimental measurement, we validate our theoretical model. The experiments verify that the output electrical power at the RBC receiver can be up to 2 W. The maximum energy Transmission distance is 2.6 m. Both the experimental and theoretical performance of the RBC system are evaluated in terms of the Transmission distance, the Transmission efficiency, and the output electrical power. Our theoretical model and experimental testbed lead to the guidelines for the RBC system design and implementation in practice.
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wireless energy Transmission Channel modeling in resonant beam charging for iot devices
arXiv: Signal Processing, 2018Co-Authors: Wei Wang, Qingqing Zhang, Hua Lin, Mingqing Liu, Xiaoyan Liang, Qingwen LiuAbstract:Power supply for Internet of Things (IoT) devices is one of the bottlenecks in IoT development. To provide perpetual power supply to IoT devices, resonant beam charging (RBC) is a promising safe, long-range and high-power wireless power transfer solution. How long distance can RBC reach and how much power can RBC transfer? In this paper, we analyze the RBC's consistent and steady operational conditions, which determine the maximum power Transmission distance. Moreover, we study the power Transmission efficiency within the operational distance, which determines the deliverable power through the RBC energy Transmission Channel. Based on this energy Transmission Channel modeling, we numerically evaluate its impacts on the RBC system performance in terms of the Transmission distance, the Transmission efficiency, and the output electrical power. The analysis leads to the guidelines for the RBC system design and implementation, which can deliver multi-Watt power over multi-meter distance wirelessly for IoT devices.
