Jihun Lee, F. Laiwalla, J. Jeong, Chester Kilfoyle, L. Larson, A. Nurmikko, Siwei Li, Siyuan Yu, V. Leung
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引用次数: 25
摘要
我们描述了一种定制的无线电源和数据传输(WPDT)链路,并分析了其在嵌入0.5 mm × 0.5 mm平面微线圈天线的CMOS传感器asic(“神经颗粒”)集成的原型植入式传感器系统中的性能。我们使用~1 GHz的近场RF在谐振3线圈架构中进行无线供电,包括在象限布局架构中植入中继线圈,以最大化覆盖面积和RF传输效率。我们在台式代理生理测试中成功地展示了跨天线截面的WPDT。对后向散射信号的解调和分析验证了数据链路的保真度。我们的研究结果表明,这种电磁耦合方案可以稳定地支持250/ cm2的芯片密度(在2cm × 2cm区域内多达1024个单独的神经粒),并且可以组合并行发射器以增加信道容量而不会产生破坏性干扰。
Wireless Power and Data Link for Ensembles of Sub-mm scale Implantable Sensors near 1GHz
We describe a custom wireless power and data transmission (WPDT) link and analyze its performance in a prototype implantable sensor system of ensembles of CMOS sensor ASICs (“Neurograins”) embedding 0.5 mm × 0.5 mm planar microcoil antennas. We use near-field RF at ~1 GHz for wireless powering in a resonant 3-coil architecture including an implanted relay coil in a quadrant layout architecture to maximize coverage area and RF transfer efficiency. We demonstrate successful WPDT across antenna cross-section in benchtop proxy physiological tests. Demodulation and analysis of backscattered signals validate the data link fidelity. Our results suggest that this electromagnetic coupling scheme can robustly support a chip density of 250/ cm2(up to 1024 individual Neurograins in a 2 cm × 2 cm area) and parallel transmitters can be combined to multiply the channel capacity without destructive interference.
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