Litcius/Paper detail

Simulation of Bipolar-Type Resistive Switching Devices Using a Recursive Approach to the Dynamic Memdiode Model

E. Miranda, Eszter Piros, Fernando Aguirre, Taejin Kim, Philipp Schreyer, J. Gehrunger, T. Oster, Klaus Hofmann, J. Suñé, Christian Hochberger, Lambert Alff

2023IEEE Electron Device Letters14 citationsDOI

Abstract

Very often researchers in the field of resistive switching devices or memristors need to model their experimental data using a compact representation without dealing with the complexities of a circuit simulator or a differential equation solver. Moreover, once a given device is simulated, one is always tempted to find out what would be the effect of changing the value or dependence of one or several model parameters in a simple and straightforward way. In this letter, we provide such a tool. The dynamic memdiode model for the conduction characteristics of resistive switching devices has been rewritten and simplified so as to comply with these demanding requirements. The model formulation is essentially the same except that it is now expressed using a recursive approach fully compatible with its original foundations. This has been possible thanks to the inherent symmetry of the model equations and to the unification of the physical description of the set and reset processes. We show how the proposed approach can be used as a test bench for different hypotheses, in particular, we focus here on the role played by the characteristic switching times during the state transitions.

Topics & Concepts

MemristorComputer scienceRepresentation (politics)SolverUnificationReset (finance)Resistive touchscreenSet (abstract data type)Thermal conductionResistive random-access memoryField (mathematics)Differential equationElectronic engineeringElectrical engineeringPhysicsMathematicsEngineeringVoltageQuantum mechanicsComputer visionFinancial economicsEconomicsPure mathematicsPoliticsProgramming languagePolitical scienceLawAdvanced Memory and Neural ComputingFerroelectric and Negative Capacitance DevicesNeural dynamics and brain function