High Accuracy Localization for Miniature Ingestible Devices Using Mutual Inductance

Lichen Yao;Sadeque Reza Khan;Guido Dolmans;Jac Romme;Srinjoy Mitra
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Abstract

This article demonstrates an inductively coupled high-accuracy localization system for miniature ingestible devices. It utilizes an inductance double capacitances-series capacitance (LCC-S) compensation architecture that enables mutual inductance measurement at primary side that is positioned outside the human body and less constrained by power budget and size than the miniature ingestible. Depending on the secondary circuit architecture, only limited and simple cooperative measurements are needed from the ingestible secondary side, which saves power and area in the miniature device. The errors in the system are modeled thoroughly, providing insights about system require-ments for a particular localization accuracy target for efficient design and to identify key building blocks with large influence on overall performance. The model shows that sub-centimeter localization root-mean-square error (RMSE) can be achieved with a modest external ADC (18bit) using three primary coils and three secondary coils. The localization is verified along a complete small intestine tract with realistic dimensions. The proposed model is verified by simulation and experiment showing that at the selected frequency range up to 5 MHz the body has no influence on the accuracy. The use of 0.9% saline as phantom is proposed which guarantees the analysis validity for all body types.
利用互感实现微型可摄入设备的高精度定位
本文展示了一种用于微型可摄入设备的电感耦合高精度定位系统。该系统采用电感双电容-串联电容(LCC-S)补偿架构,可在初级侧进行互感测量,初级侧位于人体外,与微型可摄取设备相比,其功率预算和尺寸限制较少。根据次级电路结构的不同,只需从可摄取的次级侧进行有限而简单的协同测量,从而节省了微型设备的功耗和面积。对系统中的误差进行了全面建模,从而深入了解了特定定位精度目标对系统的要求,以便进行高效设计,并确定对整体性能有重大影响的关键构件。模型显示,使用三个初级线圈和三个次级线圈,通过适度的外部 ADC(18 位),可以实现亚厘米级的定位均方根误差(RMSE)。定位结果沿着具有真实尺寸的完整小肠道进行了验证。通过模拟和实验验证了所提出的模型,结果表明,在所选频率范围(最高 5 MHz)内,人体对精确度没有影响。建议使用 0.9% 生理盐水作为人体模型,这保证了对所有身体类型的分析有效性。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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