IEEE Trans Biomed Circuits Syst. 2020 Apr;14(2):221-231. doi: 10.1109/TBCAS.2020.2969910. Epub 2020 Feb 4.
This paper presents an adaptable dictionary-based feature extraction approach for spike sorting offering high accuracy and low computational complexity for implantable applications. It extracts and learns identifiable features from evolving subspaces through matched unsupervised subspace filtering. To provide compatibility with the strict constraints in implantable devices such as the chip area and power budget, the dictionary contains arrays of {-1, 0 and 1} and the algorithm need only process addition and subtraction operations. Three types of such dictionary were considered. To quantify and compare the performance of the resulting three feature extractors with existing systems, a neural signal simulator based on several different libraries was developed. For noise levels σ between 0.05 and 0.3 and groups of 3 to 6 clusters, all three feature extractors provide robust high performance with average classification errors of less than 8% over five iterations, each consisting of 100 generated data segments. To our knowledge, the proposed adaptive feature extractors are the first able to classify reliably 6 clusters for implantable applications. An ASIC implementation of the best performing dictionary-based feature extractor was synthesized in a 65-nm CMOS process. It occupies an area of 0.09 mm and dissipates up to about 10.48 μW from a 1 V supply voltage, when operating with 8-bit resolution at 30 kHz operating frequency.
本文提出了一种基于字典的自适应特征提取方法,用于尖峰分类,为植入式应用提供了高精度和低计算复杂度。它通过匹配无监督子空间滤波从不断发展的子空间中提取和学习可识别的特征。为了与植入设备(如芯片面积和功率预算)的严格限制兼容,字典包含{-1、0 和 1}的数组,并且算法仅需要处理加减运算。考虑了三种这样的字典。为了量化和比较三种特征提取器与现有系统的性能,基于几个不同的库开发了基于神经网络信号模拟器。对于噪声水平 σ 在 0.05 到 0.3 之间以及 3 到 6 个簇的组,所有三种特征提取器都提供了稳健的高性能,在五次迭代中平均分类错误率低于 8%,每次迭代由 100 个生成的数据段组成。据我们所知,所提出的自适应特征提取器是第一个能够可靠地对植入应用进行 6 聚类分类的。基于字典的最佳性能特征提取器的 ASIC 实现已在 65nm CMOS 工艺中合成。当以 8 位分辨率在 30kHz 工作频率下工作时,它占用 0.09mm 的面积,并从 1V 电源消耗高达约 10.48μW 的功率。
