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    Journals >Laser & Optoelectronics Progress >Volume 59 >Issue 7 >Page 0700002 > Article
    • Laser & Optoelectronics Progress
    • Vol. 59, Issue 7, 0700002 (2022)
    Healthcare Wireless Optical Communications Technology: Advances, Prototypes and Prospects
    Jupeng Ding1、*, Zhiling Yi2, Jintao Wang3, Hui Yang3, Lili Wang4, Jiong Zheng1, Kai Zhao1, and Linlin Zhang1
    Author Affiliations
  • 1Key Laboratory of Signal Detection and Processing in Xinjiang Uygur Autonomous Region, College of Information Science and Engineering, Xinjiang University, Urumqi , Xinjiang 830046, China
  • 2China Mobile Research Institute, Beijing 100053, China
  • 3Beijing National Research Center for Information Science and Technology, Department of Electronic Engineering, Tsinghua University, Beijing 100084, China
  • 4School of Information and Electrical Engineering, Ludong University, Yantai , Shandong 264025, China
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    DOI: 10.3788/LOP202259.0700002 Cite this Article Set citation alerts
    Jupeng Ding, Zhiling Yi, Jintao Wang, Hui Yang, Lili Wang, Jiong Zheng, Kai Zhao, Linlin Zhang. Healthcare Wireless Optical Communications Technology: Advances, Prototypes and Prospects[J]. Laser & Optoelectronics Progress, 2022, 59(7): 0700002 Copy Citation Text show less
    Diverse potential applications of wireless optical techniques in healthcare domain[8]
    Fig. 1. Diverse potential applications of wireless optical techniques in healthcare domain[8]
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    Typical wearable wireless optical healthcare monitoring device[10]
    Fig. 2. Typical wearable wireless optical healthcare monitoring device[10]
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    Illustration of scenes with active wireless optical link[16]
    Fig. 3. Illustration of scenes with active wireless optical link[16]
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    Human body models in wireless optical body area link. (a) Two-dimensional basic model (8 faces); (b) three-dimensional full model (1796 faces)[16]
    Fig. 4. Human body models in wireless optical body area link. (a) Two-dimensional basic model (8 faces); (b) three-dimensional full model (1796 faces)[16]
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    RFID and wireless optical passive link transmission scheme. (a) Hybrid RFID-OWC system model; (b) position relationship of tag and reader[19]
    Fig. 5. RFID and wireless optical passive link transmission scheme. (a) Hybrid RFID-OWC system model; (b) position relationship of tag and reader[19]
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    Hybrid passive-active wireless optical health monitoring system architecture[17]
    Fig. 6. Hybrid passive-active wireless optical health monitoring system architecture[17]
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    Applications of wireless optical relay link in RF sensitive environment[23]
    Fig. 7. Applications of wireless optical relay link in RF sensitive environment[23]
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    Healthcare wireless optical communication system based on amplification and forward relay link[21-23]
    Fig. 8. Healthcare wireless optical communication system based on amplification and forward relay link[21-23]
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    Medical VLC system[36]. (a) Architecture of indoor VLC system in a hospital environment using LED devices; (b) ECG signal received via VLC medical information system
    Fig. 9. Medical VLC system[36]. (a) Architecture of indoor VLC system in a hospital environment using LED devices; (b) ECG signal received via VLC medical information system
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    System architecture of mobile health–monitoring system using VLC transmission[27]
    Fig. 10. System architecture of mobile health–monitoring system using VLC transmission[27]
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    Wearable EEG transmission experiment[24]. (a) Wearable EEG measurement setup (side view); (b) front view with different electrode placement
    Fig. 11. Wearable EEG transmission experiment[24]. (a) Wearable EEG measurement setup (side view); (b) front view with different electrode placement
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    Prototype of receiver module. (a) Receiver container designed using three-dimensional printer; (b) components of module; (c) average voltage tracking circuit for each color channel[30]
    Fig. 12. Prototype of receiver module. (a) Receiver container designed using three-dimensional printer; (b) components of module; (c) average voltage tracking circuit for each color channel[30]
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    IMD has an embedded light sensor and smartphone flashlight acts as a light source[1]
    Fig. 13. IMD has an embedded light sensor and smartphone flashlight acts as a light source[1]
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    Jupeng Ding, Zhiling Yi, Jintao Wang, Hui Yang, Lili Wang, Jiong Zheng, Kai Zhao, Linlin Zhang. Healthcare Wireless Optical Communications Technology: Advances, Prototypes and Prospects[J]. Laser & Optoelectronics Progress, 2022, 59(7): 0700002
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    Paper Information
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