基于动态固体电解质ZnO薄膜晶体管的暂态数据分类库计算

IF 1.9 Q3 ENGINEERING, ELECTRICAL & ELECTRONIC
A. Gaurav, Xiaoyao Song, S. Manhas, Aditya Gilra, E. Vasilaki, P. Roy, M. M. De Souza
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引用次数: 4

摘要

顺序和时间数据的处理对于计算机视觉和语音识别至关重要,这是人工智能(AI)最常见的两个应用。水库计算(RC)是人工智能的一个分支,与传统的递归神经网络(rnn)相比,它提供了一个高效的框架,以较低的训练成本处理时间输入。然而,尽管付出了巨大的努力,但到目前为止,基于双端记忆电阻器的储层只能通过在整个序列结束时读取一次电导状态来处理序列数据。该方法降低了与来自储层的信号数量相关的维数,从而降低了储层系统的整体性能。更高的维度通过读取输入的更大的时空特征集来促进原本不可分割的输入的分离。此外,基于忆阻器的储层可以使用多个脉冲速率,快速或慢速读取(立即读取或在序列结束后引入延迟),也可以使用兴奋脉冲来增强储层状态的维度。这增加了储层系统的复杂性,降低了功率效率。在本文中,我们展示了第一个基于动态三端固体电解质ZnO/Ta2O5薄膜晶体管的储层计算系统,该晶体管在低于100°C的温度下制造。该装置固有的非线性和动态记忆导致了丰富的储层状态分离特性,据我们所知,使用基于电子电荷的系统对手写数字进行分类的最高准确率为94.44%。这种改进归因于通过在每个脉冲之后读取储层状态而不是在序列结束时读取储层状态来增加储层的维度。第三终端通过漏极处的小读脉冲,使读操作处于关断状态,即当在闸极终端没有施加脉冲时。这从根本上允许多次读取操作而不增加能耗,这在传统的双端记忆电阻器中是不可能的。此外,我们还表明,即使在多次写入脉冲后,设备也不会饱和,这表明该设备能够处理更长的序列。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Reservoir Computing for Temporal Data Classification Using a Dynamic Solid Electrolyte ZnO Thin Film Transistor
The processing of sequential and temporal data is essential to computer vision and speech recognition, two of the most common applications of artificial intelligence (AI). Reservoir computing (RC) is a branch of AI that offers a highly efficient framework for processing temporal inputs at a low training cost compared to conventional Recurrent Neural Networks (RNNs). However, despite extensive effort, two-terminal memristor-based reservoirs have, until now, been implemented to process sequential data by reading their conductance states only once, at the end of the entire sequence. This method reduces the dimensionality, related to the number of signals from the reservoir and thereby lowers the overall performance of reservoir systems. Higher dimensionality facilitates the separation of originally inseparable inputs by reading out from a larger set of spatiotemporal features of inputs. Moreover, memristor-based reservoirs either use multiple pulse rates, fast or slow read (immediately or with a delay introduced after the end of the sequence), or excitatory pulses to enhance the dimensionality of reservoir states. This adds to the complexity of the reservoir system and reduces power efficiency. In this paper, we demonstrate the first reservoir computing system based on a dynamic three terminal solid electrolyte ZnO/Ta2O5 Thin-film Transistor fabricated at less than 100°C. The inherent nonlinearity and dynamic memory of the device lead to a rich separation property of reservoir states that results in, to our knowledge, the highest accuracy of 94.44%, using electronic charge-based system, for the classification of hand-written digits. This improvement is attributed to an increase in the dimensionality of the reservoir by reading the reservoir states after each pulse rather than at the end of the sequence. The third terminal enables a read operation in the off state, that is when no pulse is applied at the gate terminal, via a small read pulse at the drain. This fundamentally allows multiple read operations without increasing energy consumption, which is not possible in the conventional two-terminal memristor counterpart. Further, we have also shown that devices do not saturate even after multiple write pulses which demonstrates the device’s ability to process longer sequences.
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