Experimental demonstration of a second-order memristor and its ability to biorealistically implement synaptic plasticity.

Journal: Nano letters

PMID: 25710872

Abstract

Memristors have been extensively studied for data storage and low-power computation applications. In this study, we show that memristors offer more than simple resistance change. Specifically, the dynamic evolutions of internal state variables allow an oxide-based memristor to exhibit Ca(2+)-like dynamics that natively encode timing information and regulate synaptic weights. Such a device can be modeled as a second-order memristor and allow the implementation of critical synaptic functions realistically using simple spike forms based solely on spike activity.

Authors

Sungho Kim

Department of Surgery, Seoul National University Bundang Hospital, Seoul National University College of Medicine , Seongnam-si, Korea.
Chao Du
Patrick Sheridan
Wen Ma
ShinHyun Choi
Wei D Lu

Keywords

Action Potentials Animals Biomimetic Materials Computer Storage Devices Computer-Aided Design Electric Impedance Equipment Design Equipment Failure Analysis Humans Memory Nerve Net Neural Networks, Computer Neuronal Plasticity Synaptic Transmission

External Resources

View on PubMed Access via DOI PubMed (25710872)

Experimental demonstration of a second-order memristor and its ability to biorealistically implement synaptic plasticity.

Abstract

Authors

Keywords

External Resources

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