A 128-Channel Extreme Learning Machine-Based Neural Decoder for Brain Machine Interfaces

IF 3.8 2区医学 Q2 ENGINEERING, BIOMEDICAL IEEE Transactions on Biomedical Circuits and Systems Pub Date : 2015-09-22 DOI:10.1109/TBCAS.2015.2483618

Yi Chen, Enyi Yao, A. Basu

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引用次数: 80

Abstract

Currently, state-of-the-art motor intention decoding algorithms in brain-machine interfaces are mostly implemented on a PC and consume significant amount of power. A machine learning coprocessor in 0.35- μm CMOS for the motor intention decoding in the brain-machine interfaces is presented in this paper. Using Extreme Learning Machine algorithm and low-power analog processing, it achieves an energy efficiency of 3.45 pJ/MAC at a classification rate of 50 Hz. The learning in second stage and corresponding digitally stored coefficients are used to increase robustness of the core analog processor. The chip is verified with neural data recorded in monkey finger movements experiment, achieving a decoding accuracy of 99.3% for movement type. The same coprocessor is also used to decode time of movement from asynchronous neural spikes. With time-delayed feature dimension enhancement, the classification accuracy can be increased by 5% with limited number of input channels. Further, a sparsity promoting training scheme enables reduction of number of programmable weights by ≈ 2X.

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基于128通道极限学习机的脑机接口神经解码器

目前，脑机接口中最先进的动作意图解码算法大多是在PC上实现的，并且消耗大量的能量。本文提出了一种用于脑机接口中运动意图解码的0.35 μm CMOS机器学习协处理器。采用Extreme Learning Machine算法和低功耗模拟处理，在50 Hz的分类速率下实现了3.45 pJ/MAC的能量效率。第二阶段的学习和相应的数字存储系数被用来提高核心模拟处理器的鲁棒性。用猴指运动实验记录的神经数据对芯片进行了验证，对运动类型的解码准确率达到99.3%。同样的协处理器也用于解码来自异步神经尖峰的运动时间。通过对时滞特征维数的增强，在输入通道数量有限的情况下，分类准确率可提高5%。此外，稀疏性促进训练方案使可编程权值的数量减少约2X。

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来源期刊

IEEE Transactions on Biomedical Circuits and Systems 工程技术-工程：电子与电气

CiteScore

10.00

自引率

13.70%

发文量

174

审稿时长

3 months

期刊介绍： The IEEE Transactions on Biomedical Circuits and Systems addresses areas at the crossroads of Circuits and Systems and Life Sciences. The main emphasis is on microelectronic issues in a wide range of applications found in life sciences, physical sciences and engineering. The primary goal of the journal is to bridge the unique scientific and technical activities of the Circuits and Systems Society to a wide variety of related areas such as: • Bioelectronics • Implantable and wearable electronics like cochlear and retinal prosthesis, motor control, etc. • Biotechnology sensor circuits, integrated systems, and networks • Micropower imaging technology • BioMEMS • Lab-on-chip Bio-nanotechnology • Organic Semiconductors • Biomedical Engineering • Genomics and Proteomics • Neuromorphic Engineering • Smart sensors • Low power micro- and nanoelectronics • Mixed-mode system-on-chip • Wireless technology • Gene circuits and molecular circuits • System biology • Brain science and engineering: such as neuro-informatics, neural prosthesis, cognitive engineering, brain computer interface • Healthcare: information technology for biomedical, epidemiology, and other related life science applications. General, theoretical, and application-oriented papers in the abovementioned technical areas with a Circuits and Systems perspective are encouraged to publish in TBioCAS. Of special interest are biomedical-oriented papers with a Circuits and Systems angle.