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    科学领域:

    • 生物医学工程 生物医学工程
    • 无线通信无线通信
    • 天线设计天线设计

    背景情况:

    • 身体区域网络 (BAN) 需要在可穿戴设备和植入设备之间进行无通信.
    • 现有的体内通信 (IBC) 方法经常面临复杂性,侵入性或数据速率限制的挑战.
    • 脂肪组织为信号传播提供了一个独特的媒介,为非侵入性通信链接提供了潜力.

    研究的目的:

    • 设计和验证一种非侵入性的基于天线的可穿戴脂肪体内通信 (Fat-IBC) 系统.
    • 为了使身体区域网络内的各种设备之间不间断的数据交换.
    • 通过使用现成硬件,通过人类脂肪层实现高数据速率.

    主要方法:

    • 为Fat-IBC设计了一个简单的平面环天线,涂有PDMS,并用铁和铜带进行屏蔽.
    • 一个三层人体组织模型 (皮肤,脂肪,肌肉) 用于数值分析和天线优化.
    • 该系统使用两个相同的可穿戴天线 (Tx/Rx) 构建,并通过模拟和使用幽灵的实验研究进行验证.
    • 数据传输的特征是使用散射参数和IEEE 802.11n标准在2.4 GHz,使用Raspberry Pi计算机.

    主要成果:

    • 拟议的可穿戴天线系统通过三层幻影组织模型成功建立了Fat-IBC链接.
    • 数字模拟和实验验证证证了Fat-IBC概念的可行性.
    • 使用2.4 GHz的40 MHz带宽实现了93 Mb/s的最大链路速度,符合IEEE 802.11n标准.

    结论:

    • 开发的基于天线的非侵入性可穿戴Fat-IBC系统为身体区域网络内的高速数据通信提供了可行的解决方案.
    • 该系统利用低成本,现成的硬件和既定的无线通信标准.
    • 这种方法表明了通过人体脂肪层进行高效和可靠的通信的潜力,用于生物医学应用.