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Optimization of non-linear conductance modulation based on metal oxide memristors

Optimization of non-linear conductance modulation based on metal oxide memristors AbstractAs memristor-simulating synaptic devices have become available in recent years, the optimization on non-linearity degree (NL, related to adjacent conductance values) is unignorable in the promotion of the learning accuracy of systems. Importantly, based on the theoretical support of the Mott theory and the three partial differential equations, and the model of conductive filaments (CFs), we analyzed and summarized the optimization schemes on the physical structure and the extra stimulus signal from the internal factor and external influence, two aspects, respectively. It is worth noting that we divided the extra stimulus signals into two categories, the combined pulse signal and the feedback pulse signal. The former has an internal logical optimized phenomenon, and the composition of only two parts in each cycle leads to a simple peripheral circuit. The latter can obtain an almost linear NL curve in software stimulation because of its feature in real-time adjustment of signals, but it is complex in hardware implementation. In consideration of space and energy consumption, achieving memristor with different resistive switching (RS) layers can be another optimization scheme. Special attention should be paid to the weaker NL, which could improve learning accuracy at the system level only when the value of other non-ideal properties such as the on/off ratio is within a certain range. http://www.deepdyve.com/assets/images/DeepDyve-Logo-lg.png Nanotechnology Reviews de Gruyter

Optimization of non-linear conductance modulation based on metal oxide memristors

Liu, Huan; Wei, Min; Chen, Yuzhong
Nanotechnology Reviews , Volume 7 (5): 26 – Oct 25, 2018
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Publisher
de Gruyter
Copyright
©2018 Walter de Gruyter GmbH, Berlin/Boston
ISSN
2191-9097
eISSN
2191-9097
DOI
10.1515/ntrev-2018-0045
Publisher site
See Article on Publisher Site

Abstract

AbstractAs memristor-simulating synaptic devices have become available in recent years, the optimization on non-linearity degree (NL, related to adjacent conductance values) is unignorable in the promotion of the learning accuracy of systems. Importantly, based on the theoretical support of the Mott theory and the three partial differential equations, and the model of conductive filaments (CFs), we analyzed and summarized the optimization schemes on the physical structure and the extra stimulus signal from the internal factor and external influence, two aspects, respectively. It is worth noting that we divided the extra stimulus signals into two categories, the combined pulse signal and the feedback pulse signal. The former has an internal logical optimized phenomenon, and the composition of only two parts in each cycle leads to a simple peripheral circuit. The latter can obtain an almost linear NL curve in software stimulation because of its feature in real-time adjustment of signals, but it is complex in hardware implementation. In consideration of space and energy consumption, achieving memristor with different resistive switching (RS) layers can be another optimization scheme. Special attention should be paid to the weaker NL, which could improve learning accuracy at the system level only when the value of other non-ideal properties such as the on/off ratio is within a certain range.

Journal

Nanotechnology Reviewsde Gruyter

Published: Oct 25, 2018

References

  • Investigation of cycle-to-cycle variability in HfO2-Based OxRAM
  • Synaptic devices based on purely electronic memristors
  • Tunnel junction based memristors as artificial synapses
  • Memristor emulator for memristor circuit applications
  • Nanoionics-based three-terminal synaptic device using zinc oxide
  • Oxide resistive memory with functionalized graphene as built-in selector element
  • Improved synaptic behavior under identical pulses using AlOx/HfO2Bilayer RRAM array for neuromorphic systems
  • Complementary resistive switching in tantalum oxide-based resistive memory devices
  • Memristor with Ag-cluster-doped TiO2 films as artificial synapse for neuroinspired computing
  • Analog resistive switching behavior of Al/Nb2O5/Al device
  • The effect of different oxygen exchange layers on TaOx based RRAM devices
  • Observation of conducting filament growth in nanoscale resistive memories
  • Nanoscale cation motion in TaOx, HfOx and TiOx memristive systems
  • 3-D vertical dual-layer oxide memristive devices
  • Programmable resistance switching in nanoscale two-terminal devices
  • Resistance switching memory in perovskite oxides
  • Metal-insulator-transition near a superconducting state
  • A single-transistor silicon synapse
  • Tunable defect engineering in TiON thin films by multi-step sputtering processes: from a Schottky diode to resistive switching memory
  • Observation of conducting filament growth in nanoscale resistive memories
  • Synaptic plasticity and learning behaviors mimicked in single inorganic synapses of Pt/HfOx/ZnOx/TiN memristive system
  • Analog resistive switching behavior of Al/Nb2O5/Al device
  • ReRAM-based synaptic device for neuromorphic computing
  • Enhanced biocompatibility in anodic TaOx nanotube arrays
  • Synaptic plasticity and learning behaviours in flexible artificial synapse based on polymer/viologen system
  • Bioinspired programming of memory devices for implementing an inference engine
  • An organic terpyridyl-iron polymer based memristor for synaptic plasticity and learning behavior simulation
  • Realization of synaptic learning and memory functions in Y2O3 based memristive device fabricated by dual ion beam sputtering
  • A hybrid nanomemristor/transistor logic circuit capable of self-programming
  • Resistive random access memory (ReRAM) based on metal oxides
  • Learning abilities achieved by a single solid-state atomic switch
  • Characterization and modeling of nonfilamentary Ta/TaOx/TiO2/Ti analog synaptic device
  • Repeatable, accurate, and high speed multi-level programming of memristor 1T1R arrays for power efficient analog computing applications