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Forming‐Free Resistive Switching Memory Crosspoint Arrays for In‐Memory Machine Learning

Saverio Ricci, Piergiulio Mannocci, Matteo Farronato, Shahin Hashemkhani, Daniele Ielmini

2022Advanced Intelligent Systems28 citationsDOIOpen Access PDF

Abstract

In‐memory computing (IMC) with crosspoint arrays of resistive switching memory (RRAM) has gained wide attention for accelerating machine learning, data analysis, and deep neural networks. By IMC, matrix‐vector multiplication (MVM) can be executed in the crosspoint array in just one step, thus accelerating a broad range of tasks in machine learning and data analytics. However, a key issue for RRAM crosspoint arrays is the forming operation of the memories which limits the stability and accuracy of the conductance state in the memory device. In this work, a hardware implementation of crosspoint array of forming‐free devices for fast, energy‐efficient accelerators of MVM is reported. RRAM devices with a 1.5 nm‐thick HfO 2 layer show an initial low resistance without forming and an analogue‐mode programming behavior for high‐accuracy IMC. Accurate hardware MVM is demonstrated by experimental eigenvalue/eigenvector calculation according to the power‐iteration algorithm, with a fast convergence within about ten iterations to the correct solution. Deflation technique and principal component analysis (PCA) enable the classification of the Iris dataset with 98% accuracy compared with floating‐point implementation. These results support forming‐free crosspoint arrays for accelerating advanced machine learning with IMC.

Topics & Concepts

Resistive random-access memoryComputer scienceMultiplication (music)In-Memory ProcessingEigenvalues and eigenvectorsMatrix multiplicationArtificial neural networkResistive touchscreenCrossbar switchComputer hardwareArtificial intelligenceComputational scienceElectrical engineeringVoltageEngineeringPhysicsComputer visionTelecommunicationsInformation retrievalWeb search queryAcousticsSearch engineQuery by ExampleQuantumQuantum mechanicsAdvanced Memory and Neural ComputingFerroelectric and Negative Capacitance DevicesSemiconductor materials and devices