A 62.2dB SNDR Event-Driven Level-Crossing ADC with SAR-Assisted Delay Compensation Loop for Time-Sparse Biomedical Signal Acquisition.

Mengyu Li, Yi Huo, Shuang Song, Wanyuan Qu, Le Ye, Menglian Zhao, Zhichao Tan
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Abstract

This paper proposed an event-driven clockless level-crossing ADC (LC-ADC) suitable for biomedical applications. Thanks to the LC loop, the sampling rate of the converter automatically adapts to the input activities. Activity-dependent power consumption and data compression can thus be realized, saving system power, especially during time-sparse signal acquisition. Meanwhile, a SAR-assisted loop is exploited to resolve the loop-delay-induced distortion in conventional LC-ADC. Therefore, the resolution and power efficiency of the LC-ADC are improved effectively while maintaining the event-driven feature. Implemented in a 55nm process, the proposed LC-ADC achieves a scalable power consumption and a peak SNDR of 62.2dB for a 20kHz input. It also achieves a Walden FoM of 29.7fJ/conv.-step and a Schreier FoM of 158.6dB, which is best in class, without using off-chip calibration. Sub μW power is realized when the input frequency is below 1.5kHz. The proposed LC-ADC is also verified by simulated electrocardiogram (ECG), neural spike, and electromyogram (EMG) signals. It provides a ~7X data compression for ECG input, providing an attractive solution for time-sparse signal acquisition in biomedical applications.

用于时间稀疏生物医学信号采集的 62.2dB SNDR 事件驱动电平交叉 ADC,带有 SAR 辅助延迟补偿环路。
本文提出了一种适用于生物医学应用的事件驱动无时钟电平转换器(LC-ADC)。通过 LC 环路,转换器的采样率可自动适应输入活动。因此,可以实现与活动相关的功耗和数据压缩,从而节省系统功耗,尤其是在时间稀疏信号采集期间。同时,利用 SAR 辅助环路解决了传统 LC-ADC 中环路延迟引起的失真问题。因此,在保持事件驱动特性的同时,LC-ADC 的分辨率和能效得到了有效提高。采用 55 纳米工艺实现的 LC-ADC 功耗可调,20kHz 输入的峰值 SNDR 为 62.2dB。它还实现了 29.7fJ/conv.-step 的 Walden FoM 和 158.6dB 的 Schreier FoM,这在同类产品中是最好的,而且无需使用片外校准。当输入频率低于 1.5kHz 时,可实现低于 μW 的功率。拟议的 LC-ADC 还通过模拟心电图(ECG)、神经尖峰和肌电图(EMG)信号进行了验证。它为心电图输入提供了约 7 倍的数据压缩,为生物医学应用中的时间稀疏信号采集提供了有吸引力的解决方案。
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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