28nm HKMG ffet技术中多通道流数据的高能效边缘推断

2019 Symposium on VLSI Technology Pub Date : 2019-06-09 DOI:10.23919/VLSIT.2019.8776525

S. Dutta, W. Chakraborty, J. Gomez, K. Ni, S. Joshi, S. Datta

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引用次数: 5

摘要

我们提出了一种对多通道生物医学传感器数据进行极节能推理的系统。我们利用铁电场效应管(FeFET)直接对模拟传感器信号进行分类。我们演示了:(i)电压控制的多域铁电极化开关在28nm HKMG FeFET技术中获得8个不同的跨导$(\text{g}_{\text{m}})$状态[1]，(ii)在感兴趣的带宽上，$\text{g}_{\text{m}}$的30倍可调谐范围，(iii)成功实现了对CHB-MIT EEG数据集进行癫痫检测的伪像去除，特征提取和分类，准确率为98.46%，$< 0.375/\text{hr}$。(iv) 47 fJ/MAC的超低能量，与替代混合信号MAC相比，面积提高了1000倍。

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Energy-Efficient Edge Inference on Multi-Channel Streaming Data in 28nm HKMG FeFET Technology

We present a system implementing extremely energy-efficient inference on multi-channel biomedical-sensor data. We leverage Ferroelectric FET (FeFET) to perform classification directly on analog sensor signals. We demonstrate: (i) voltage-controlled multi-domain ferroelectric polarization switching to obtain 8 distinct transconductance $(\text{g}_{\text{m}})$ states in a 28nm HKMG FeFET technology [1], (ii) 30x tunable range in $\text{g}_{\text{m}}$ over the bandwidth of interest, (iii) successful implementation of artifact removal, feature extraction and classification for seizure detection from CHB-MIT EEG dataset with 98.46% accuracy and $< 0.375/\text{hr}$. false alarm rate for two patients, (iv) ultra-low energy of 47 fJ/MAC with 1,000x improvement in area compared to alternative mixed-signal MAC.

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2019 Symposium on VLSI Technology

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