Milano Gianluca, Pedretti Giacomo, Montano Kevin, Ricci Saverio, Hashemkhani Shahin, Boarino Luca, Ielmini Daniele, Ricciardi Carlo
Advanced Materials Metrology and Life Sciences Division, Istituto Nazionale di Ricerca Metrologica, Turin, Italy.
Dipartimento di Elettronica, Informazione e Bioingegneria, Politecnico di Milano and IU.NET, Milan, Italy.
Nat Mater. 2022 Feb;21(2):195-202. doi: 10.1038/s41563-021-01099-9. Epub 2021 Oct 4.
Neuromorphic computing aims at the realization of intelligent systems able to process information similarly to our brain. Brain-inspired computing paradigms have been implemented in crossbar arrays of memristive devices; however, this approach does not emulate the topology and the emergent behaviour of biological neuronal circuits, where the principle of self-organization regulates both structure and function. Here, we report on in materia reservoir computing in a fully memristive architecture based on self-organized nanowire networks. Thanks to the functional synaptic connectivity with nonlinear dynamics and fading memory properties, the designless nanowire complex network acts as a network-wide physical reservoir able to map spatio-temporal inputs into a feature space that can be analysed by a memristive resistive switching memory read-out layer. Computing capabilities, including recognition of spatio-temporal patterns and time-series prediction, show that the emergent memristive behaviour of nanowire networks allows in materia implementation of brain-inspired computing paradigms characterized by a reduced training cost.
神经形态计算旨在实现能够像我们的大脑一样处理信息的智能系统。受大脑启发的计算范式已在忆阻器件的交叉阵列中实现;然而,这种方法并未模拟生物神经元回路的拓扑结构和涌现行为,在生物神经元回路中,自组织原理调节着结构和功能。在此,我们报告了基于自组织纳米线网络的全忆阻架构中的材料内储层计算。由于具有非线性动力学和衰退记忆特性的功能性突触连接,无设计的纳米线复杂网络充当了全网络的物理储层,能够将时空输入映射到一个可以由忆阻电阻开关存储器读出层进行分析的特征空间。包括时空模式识别和时间序列预测在内的计算能力表明,纳米线网络的涌现忆阻行为允许以降低训练成本为特征的受大脑启发的计算范式在材料内实现。
