Experimental Verification of Memristor-Based Material Implication NAND Operation

Experimental Verification of Memristor-Based Material Implication NAND Operation

Memristors are being considered as promising devices for highly dense memory systems as well as the potential basis of new computational paradigms. In this scenario, and in relation with data processing, one of the more specific and differential logic functions is the material implication logic also...

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Veröffentlicht in:IEEE transactions on emerging topics in computing 2019-10, Vol.7 (4), p.545-552
Hauptverfasser: Maestro-Izquierdo, Marcos, Martin-Martinez, Javier, Crespo Yepes, Albert, Escudero, Manel, Rodriguez, Rosana, Nafria, Montserrat, Aymerich, Xavier, Rubio, Antonio
Format: Artikel
Sprache:eng
Schlagworte:
Aparells i instruments
Circuits
Components electrònics
Current measurement
Data processing
Electrodes
Electronic apparatus and appliances
Electrònica
Enginyeria electrònica
Flash memories
Hafnium oxide
IMPLY function
Logic
Logic gates
material implication
Memory devices
memristive circuits
Memristors
NAND gate implementation
Program verification (computers)
Resistance
resistive switching
Switches
Voltage measurement
Àrees temàtiques de la UPC
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Beschreibung
Zusammenfassung:Memristors are being considered as promising devices for highly dense memory systems as well as the potential basis of new computational paradigms. In this scenario, and in relation with data processing, one of the more specific and differential logic functions is the material implication logic also named as IMPLY logic. Many papers have been published in this framework but few of them are related with experimental works using real memristor devices. In the paper authors show the verification of the IMPLY function by using Ni/HfO2/Si manufactured devices and laboratory measurements. The proper behavior of the IMPLY structure (2 memristors) has been shown. The paper also verifies the proper operation of a two-step IMPLY-based NAND gate implementation, showing the electrical behavior of the circuit in a cycling operation. A new procedure to implement a NAND gate that requires only one step is experimentally shown as well.
ISSN:2168-6750
2168-6750
DOI:10.1109/TETC.2017.2760929