A 20µW neural recording tag with supply-current-modulated AFE in 0.13µm CMOS

Zhiming Xiao, Chun-Ming Tang, Christopher M. Dougherty, R. Bashirullah
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引用次数: 39

Abstract

Perpetual measurement of brain activity in untethered small animal in-vivo experiments requires low power micro-systems incorporating amplification, A/D conversion, and short range wireless transmission. Overall power and communication strategies depend largely on size constraints of the implant site. For extremely small implants, these systems generally call for permanently powering the implanted recording system without the use of a battery. Such systems are primarily based on low frequency and close proximity inductive links for power and communication [1]. Alternatively, in scenarios where the implant site is less constrained, the use of small batteries can provide increased communication range [2]. In this paper, we present a 20µW neural recording tag architecture that can be either remotely powered using a transponder-reader link or operated from a small battery for increased communication range. The key features that enable this increased system flexibility are the use of a supply current modulation strategy, minimizing average power consumption of the analog-front end (AFE) and allocating larger instantaneous power levels for amplification, processing, and communication, and an uplink communication scheme based on far-field backscattering or near-field load modulation with compatibility for both battery and remotely powered systems.
一个20µW的神经记录标签,带有0.13µm CMOS供电电流调制AFE
在无绳小动物体内实验中永久测量大脑活动需要低功耗微系统,包括放大,A/D转换和短距离无线传输。整体功率和通信策略在很大程度上取决于植入部位的尺寸限制。对于非常小的植入物,这些系统通常需要在不使用电池的情况下为植入的记录系统永久供电。这种系统主要基于低频和近距离感应链路,用于电力和通信[1]。或者,在植入部位限制较少的情况下,使用小型电池可以提供更大的通信范围[2]。在本文中,我们提出了一种20 μ W的神经记录标签架构,可以使用应答器-读取器链接远程供电,也可以使用小电池操作,以增加通信范围。增强系统灵活性的主要特点是采用电源电流调制策略,最大限度地降低模拟前端(AFE)的平均功耗,分配更大的瞬时功率水平用于放大、处理和通信,以及基于远场后向散射或近场负载调制的上行通信方案,兼容电池和远程供电系统。
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