Mallinson Joshua B, Steel Jamie K, Heywood Zachary E, Studholme Sofie J, Bones Philip J, Brown Simon A
The MacDiarmid Institute for Advanced Materials and Nanotechnology, School of Physical and Chemical Sciences, Te Kura Matū, University of Canterbury, Private Bag 4800, Christchurch, 8140, New Zealand.
Electrical and Computer Engineering, University of Canterbury, Private Bag 4800, Christchurch, 8140, New Zealand.
Adv Mater. 2024 Jul;36(29):e2402319. doi: 10.1002/adma.202402319. Epub 2024 May 10.
The complex self-assembled network of neurons and synapses that comprises the biological brain enables natural information processing with remarkable efficiency. Percolating networks of nanoparticles (PNNs) are complex self-assembled nanoscale systems that have been shown to possess many promising brain-like attributes and which are therefore appealing systems for neuromorphic computation. Here experiments are performed that show that PNNs can be utilized as physical reservoirs within a nanoelectronic reservoir computing framework and demonstrate successful computation for several benchmark tasks (chaotic time series prediction, nonlinear transformation, and memory capacity). For each task, relevant literature results are compiled and it is shown that the performance of the PNNs compares favorably to that previously reported from nanoelectronic reservoirs. It is then demonstrated experimentally that PNNs can be used for spoken digit recognition with state-of-the-art accuracy. Finally, a parallel reservoir architecture is emulated, which increases the dimensionality and richness of the reservoir outputs and results in further improvements in performance across all tasks.
由神经元和突触构成的复杂自组装网络组成了生物大脑,它能以极高的效率实现自然信息处理。纳米颗粒渗流网络(PNNs)是复杂的自组装纳米级系统,已被证明具有许多类似大脑的有前景的属性,因此是用于神经形态计算的有吸引力的系统。在此进行的实验表明,PNNs可在纳米电子储层计算框架内用作物理储层,并证明其在几个基准任务(混沌时间序列预测、非线性变换和存储容量)中成功实现了计算。对于每个任务,整理了相关文献结果,结果表明PNNs的性能优于先前报道的纳米电子储层。随后通过实验证明,PNNs可用于语音数字识别,且具有最先进的准确率。最后,模拟了一种并行储层架构,该架构增加了储层输出的维度和丰富度,并在所有任务中进一步提高了性能。
