AquaE-lite Hybrid-Solar-Cell Receiver-Modality for Energy-Autonomous Terrestrial and Underwater Internet-of-Things

Our goal is to develop an energy-autonomous solar cell receiver that can be integrated with a variety of smart devices to implement the Internet of Things in next-generation applications. This paper details efforts to develop such a prototype, called AquaE-lite. Owing to the capability of detecting...

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Veröffentlicht in:	IEEE photonics journal 2020-08, Vol.12 (4), p.1-1
Hauptverfasser:	Kong, Meiwei, Lin, Jiaming, Guo, Yujian, Sun, Xiaobin, Sait, Mohammed, Alkhazragi, Omar, Kang, Chun Hong, Holguin-Lerma, Jorge Alberto, Kheireddine, Malika, Ouhssain, Mustapha, Jones, Burton, Ng, Tien Khee, Ooi, Boon S.
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Sprache:	eng
Schlagworte:	Autonomy Background noise Batteries Circuits Electronic devices Electronics packaging Energy energy autonomous Energy harvesting Harbors Internet of Things OFDM Optical communication Optical wireless optical wireless communication Photovoltaic cells Receivers Remote sensors Silicon solar cell Solar cells Underwater Wireless communications Wireless networks Wireless sensor networks
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creator	Kong, Meiwei Lin, Jiaming Guo, Yujian Sun, Xiaobin Sait, Mohammed Alkhazragi, Omar Kang, Chun Hong Holguin-Lerma, Jorge Alberto Kheireddine, Malika Ouhssain, Mustapha Jones, Burton Ng, Tien Khee Ooi, Boon S.
description	Our goal is to develop an energy-autonomous solar cell receiver that can be integrated with a variety of smart devices to implement the Internet of Things in next-generation applications. This paper details efforts to develop such a prototype, called AquaE-lite. Owing to the capability of detecting low-intensity optical signals, 20-m and 30-m long-distance lighting and optical wireless communication with data rates of 1.6 Mbit/s and 1.2 Mbit/s have been achieved on a laboratory testbed, respectively. Moreover, field trials on an outdoor solar cell testbed and a port (turbid water) of the Red Sea have been conducted. Under bright sunlight, energy autonomy and 1.2-Mbit/s optical wireless communication over a transmission distance of 15 m have been implemented, which demonstrated that AquaE-lite with an elaborate receiver circuit has excellent performance in energy harvesting and resistance to background noise. In a more challenging underwater environment, 1.2-Mbit/s signals were successfully received over a transmission distance of 2 m. It indicates that energy-autonomous AquaE-lite with large detection area has promising prospects in future underwater mobile sensor networks to significantly relieve the requirement of pointing, acquisition and tracking while resolving the energy issues.
doi_str_mv	10.1109/JPHOT.2020.3013995
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This paper details efforts to develop such a prototype, called AquaE-lite. Owing to the capability of detecting low-intensity optical signals, 20-m and 30-m long-distance lighting and optical wireless communication with data rates of 1.6 Mbit/s and 1.2 Mbit/s have been achieved on a laboratory testbed, respectively. Moreover, field trials on an outdoor solar cell testbed and a port (turbid water) of the Red Sea have been conducted. Under bright sunlight, energy autonomy and 1.2-Mbit/s optical wireless communication over a transmission distance of 15 m have been implemented, which demonstrated that AquaE-lite with an elaborate receiver circuit has excellent performance in energy harvesting and resistance to background noise. In a more challenging underwater environment, 1.2-Mbit/s signals were successfully received over a transmission distance of 2 m. It indicates that energy-autonomous AquaE-lite with large detection area has promising prospects in future underwater mobile sensor networks to significantly relieve the requirement of pointing, acquisition and tracking while resolving the energy issues.</abstract><cop>Piscataway</cop><pub>IEEE</pub><doi>10.1109/JPHOT.2020.3013995</doi><tpages>1</tpages><oa>free_for_read</oa></addata></record>
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subjects	Autonomy Background noise Batteries Circuits Electronic devices Electronics packaging Energy energy autonomous Energy harvesting Harbors Internet of Things OFDM Optical communication Optical wireless optical wireless communication Photovoltaic cells Receivers Remote sensors Silicon solar cell Solar cells Underwater Wireless communications Wireless networks Wireless sensor networks
title	AquaE-lite Hybrid-Solar-Cell Receiver-Modality for Energy-Autonomous Terrestrial and Underwater Internet-of-Things
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