Magnetoeletric Backscatter Communication for Millimeter-Sized Wireless Biomedical Implants

IF 0.7 Q4 TELECOMMUNICATIONS GetMobile-Mobile Computing & Communications Review Pub Date : 2023-05-17 DOI:10.1145/3599184.3599192

Zhanghao Yu, Fatima T. Alrashdan, Wen Wang, M. Parker, Xinyu Chen, Frank Y. Chen, Joshua Woods, Zhiyu Chen, Jacob T. Robinson, Kaiyuan Yang

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引用次数: 1

Abstract

Magnetoelectric power transfer has shown remarkable promise for the development of wireless millimetric bioelectronic implants with its low tissue absorption, high efficiency, and low misalignment sensitivity. Utilizing the same physical mechanism for power and communication is critical for implant miniaturization. For the first time, we designed and demonstrated near-zero power magnetoelectric backscatter from mm-sized implants by exploiting the converse magnetostriction effects. The prototype system consists of an 8.2-mm3 wireless implant integrating an application-specific integrated circuit (ASIC) that achieves frequency-shift-keying backscattering via capacitive load modulation and a custom transceiver demodulating data through frequency-to-digital conversion. The magnetoelectric backscatter archives > 1 kbps data rate at the 335-kHz carrier frequency, with a communication distance greater than 2 cm and a bit error rate (BER) less than 1E-3.

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毫米尺寸无线生物医学植入物的磁电反向散射通信

磁电传输技术以其低组织吸收、高效率、低错位灵敏度等优点，为无线毫米生物电子植入物的开发提供了广阔的前景。利用相同的物理机制来供电和通信是植入物小型化的关键。我们首次利用反向磁致伸缩效应，设计并演示了毫米尺寸植入物的近零功率磁电后向散射。该原型系统包括一个8.2 mm3的无线植入物，集成了一个专用集成电路(ASIC)，该集成电路通过电容负载调制实现移频键控后向散射，并通过频率到数字转换实现自定义收发器解调数据。磁电反向散射在335 khz载波频率下的数据速率> 1 kbps，通信距离大于2 cm，误码率小于1E-3。

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