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Low Conductance State Drift Characterization and Mitigation in Resistive Switching Memories (RRAM) for Artificial Neural Networks

Andrea Baroni, Artem Glukhov, Eduardo Pérez, Christian Wenger, Daniele Ielmini, P. Olivo, Cristian Zambelli

2022IEEE Transactions on Device and Materials Reliability36 citationsDOIOpen Access PDF

Abstract

The crossbar structure of Resistive-switching random access memory (RRAM) arrays enabled the In-Memory Computing circuits paradigm, since they imply the native acceleration of a crucial operations in this scenario, namely the Matrix-Vector-Multiplication (MVM). However, RRAM arrays are affected by several issues materializing in conductance variations that might cause severe performance degradation. A critical one is related to the drift of the low conductance states appearing immediately at the end of program and verify algorithms that are mandatory for an accurate multi-level conductance operation. In this work, we analyze the benefits of a new programming algorithm that embodies Set and Reset switching operations to achieve better conductance control and lower variability. Data retention analysis performed with different temperatures for 168 hours evidence its superior performance with respect to standard programming approach. Finally, we explored the benefits of using our methodology at a higher abstraction level, through the simulation of an Artificial Neural Network for image recognition task (MNIST dataset). The accuracy achieved shows higher performance stability over temperature and time.

Topics & Concepts

Resistive random-access memoryMNIST databaseComputer scienceCrossbar switchArtificial neural networkAbstractionConductanceIn-Memory ProcessingTask (project management)Reset (finance)Electronic engineeringArtificial intelligenceElectrical engineeringVoltageEngineeringMathematicsFinancial economicsSearch engineQuery by ExampleInformation retrievalTelecommunicationsCombinatoricsPhilosophySystems engineeringWeb search queryEconomicsEpistemologyAdvanced Memory and Neural ComputingFerroelectric and Negative Capacitance DevicesMachine Learning and ELM