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采用22纳米全耗尽型绝缘层上硅(FDSOI)技术、集成特征提取、压缩和硬件加速器的用于神经假体的68通道神经信号处理片上系统。

68-channel neural signal processing system-on-chip with integrated feature extraction, compression, and hardware accelerators for neuroprosthetics in 22 nm FDSOI.

作者信息

Guo Liyuan, Weiße Annika, Zeinolabedin Seyed Mohammad Ali, Schüffny Franz Marcus, Stolba Marco, Ma Qier, Wang Zhuo, Scholze Stefan, Dixius Andreas, Berthel Marc, Partzsch Johannes, Walter Dennis, Ellguth Georg, Höppner Sebastian, George Richard, Mayr Christian

机构信息

Faculty of Electrical and Computer Engineering, School of Engineering Sciences, Dresden University of Technology, Dresden, Germany.

Department of Electrical and Computer Engineering, College of Engineering, University of Utah, Salt Lake City, UT, United States.

出版信息

Front Neurosci. 2024 Oct 23;18:1432750. doi: 10.3389/fnins.2024.1432750. eCollection 2024.

DOI:10.3389/fnins.2024.1432750
PMID:39513048
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11541109/
Abstract

INTRODUCTION

Multi-channel electrophysiology systems for recording of neuronal activity face significant data throughput limitations, hampering real-time, data-informed experiments. These limitations impact both experimental neurobiology research and next-generation neuroprosthetics.

METHODS

We present a novel solution that leverages the high integration density of 22nm fully-depleted silicon-on-insulator technology to address these challenges. The proposed highly integrated programmable System-on-Chip (SoC) comprises 68-channel 0.41 μW/Ch recording frontends, spike detectors, 16-channel 0.87-4.39 μW/Ch action potentials and 8-channel 0.32 μW/Ch local field potential codecs, as well as a multiply-accumulate-assisted power-efficient processor operating at 25 MHz (5.19 μW/MHz). The system supports on-chip training processes for compression, training, and inference for neural spike sorting. The spike sorting achieves an average accuracy of 91.48 or 94.12% depending on the utilized features. The proposed programmable SoC is optimized for reduced area (9 mm) and power. On-chip processing and compression capabilities free up the data bottlenecks in data transmission (up to 91% space saving ratio), and moreover enable a fully autonomous yet flexible processor-driven operation.

DISCUSSION

Combined, these design considerations overcome data-bottlenecks by allowing on-chip feature extraction and subsequent compression.

摘要

引言

用于记录神经元活动的多通道电生理系统面临着显著的数据吞吐量限制,这阻碍了实时的、基于数据的实验。这些限制对实验神经生物学研究和下一代神经假体都产生了影响。

方法

我们提出了一种新颖的解决方案,利用22纳米全耗尽绝缘体上硅技术的高集成密度来应对这些挑战。所提出的高度集成的可编程片上系统(SoC)包括68通道、每通道0.41微瓦的记录前端、尖峰探测器、16通道、每通道0.87 - 4.39微瓦的动作电位以及8通道、每通道0.32微瓦的局部场电位编解码器,还有一个以25兆赫兹运行(每兆赫兹5.19微瓦)的乘法累加辅助的低功耗处理器。该系统支持用于神经尖峰分类的压缩、训练和推理的片上训练过程。根据所使用的特征,尖峰分类的平均准确率达到91.48%或94.12%。所提出的可编程SoC针对减小面积(9平方毫米)和功耗进行了优化。片上处理和压缩能力消除了数据传输中的数据瓶颈(节省高达91%的空间),并且还实现了完全自主且灵活的处理器驱动操作。

讨论

综合起来,这些设计考量通过允许片上特征提取和后续压缩克服了数据瓶颈。

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