Memcapacitor and Meminductor Circuit Emulators: A Review

This research was funded by the Japanese KAKENHI through Grant Number JP18k04275 and Spanish Ministry of Education, Culture, and Sport (MECD), through Project TEC2017-89955-P and Grant Numbers: FPU16/01451 and FPU16/04043.In 1971, Prof. L. Chua theoretically introduced a new circuit element, which exhibited a different behavior from that displayed by any of the three known passive elements: the resistor, the capacitor or the inductor. This element was called memristor, since its behavior corresponded to a resistor with memory. Four decades later, the concept of mem-elements was extended to the other two circuit elements by the definition of the constitutive equations of both memcapacitors and meminductors. Since then, the non-linear and non-volatile properties of these devices have attracted the interest of many researches trying to develop a wide range of applications. However, the lack of solid-state implementations of memcapacitors and meminductors make it necessary to rely on circuit emulators for the use and investigation of these elements in practical implementations. On this basis, this review gathers the current main alternatives presented in the literature for the emulation of both memcapacitors and meminductors. Different circuit emulators have been thoroughly analyzed and compared in detail, providing a wide range of approaches that could be considered for the implementation of these devices in future designs.Ministry of Education, Culture, Sports, Science and Technology, Japan (MEXT) Japan Society for the Promotion of Science Grants-in-Aid for Scientific Research (KAKENHI) JP18k04275Spanish Ministry of Education, Culture, and Sport (MECD) TEC2017-89955-P FPU16/01451 FPU16/0404

OTA Based Mem-capacitor Validation and Implementation Using Commercially Available IC

This paper discusses a mem-capacitor circuit which is based on two MO-OTA along with a multiplier and 4 passive elements. This circuit is a charge-controlled memcapacitor emulator which is independent of any memristor also it consists the feature of electronic tunability. Additionally, this circuit is simpler and uses less hardware because it lacks a mutator and uses fewer active-passive components. The circuit behaviour is justified through various simulations in cadence Orcad tool with 180nm CMOS TSMC parameters. Additionally, conclusions from simulations and theory are validated experimentally through commercially available IC

OTA Based Mem-capacitor Validation and Implementation Using Commercially Available IC

This paper discusses a mem-capacitor circuit which is based on two MO-OTA along with a multiplier and 4 passive elements. This circuit is a charge-controlled memcapacitor emulator which is independent of any memristor also it consists the feature of electronic tunability. Additionally, this circuit is simpler and uses less hardware because it lacks a mutator and uses fewer active-passive components. The circuit behaviour is justified through various simulations in cadence Orcad tool with 180nm CMOS TSMC parameters. Additionally, conclusions from simulations and theory are validated experimentally through commercially available IC

Simple Floating Voltage-Controlled Memductor Emulator for Analog Applications

The topic of memristive circuits is a novel topic in circuit theory that has become of great importance due to its unique behavior which is useful in different applications. But since there is a lack of memristor samples, a memristor emulator is used instead of a solid state memristor. In this paper, a new simple floating voltage-controlled memductor emulator is introduced which is implemented using commercial off the shelf (COTS) realization. The mathematical modeling of the proposed circuit is derived to match the theoretical model. The proposed circuit is tested experimentally using different excitation signals such as sinusoidal, square, and triangular waves showing an excellent matching with previously reported simulations

Synthesis of memristive one-port circuits with piecewise-smooth characteristics

A generalized approach for the implementation of memristive two-terminal circuits with piesewise-smooth characteristics is proposed on the example of a multifunctional circuit based on a transistor switch. Two versions of the circuit are taken into consideration: an experimental model of the piecewise-smooth memristor (Chua's memristor) and a piecewise-smooth memristive capacitor. Physical experiments are combined with numerical modelling of the discussed circuit models. Thus, it is demonstrated that the considered circuit is a flexible solution for synthesis of a wide range of memristive systems with tuneable characteristics.Comment: 3 pages, 3 figure

El memristor, aplicaciones circuitales con amplificadores operacionales

En esencia un elemento de circuito pasivo es un componente de vital importancia en el diseño de circuitos eléctricos y electrónicos, pues es el medio por el cual la energía interactúa en forma de almacenamiento o absorción. Se disponen de tres elementos básicos en la teoría clásica de circuitos los cuales son llamados el capacitor (descubierto en 1745), el resistor (descubierto en 1827) y el inductor (descubierto en 1831), pero en el año de 1971 un profesor de ingeniería eléctrica de la universidad de California, Berkeley predijo la existencia de un cuarto dispositivo fundamental, llamado el memristor comprobando que no era posible crear un duplicado de este elemento con la combinación de los otros tres dispositivos, por lo tanto, según dicha aseveración el memristor es un dispositivo fundamental. El presente trabajo está enfocado en brindar una breve visión de las aplicaciones, comportamientos, modelado matemático y adecuación de amplificadores operacionales a la tarea de estudiar la interacción dinámica de este dispositivo de dos terminales hacia usos menos teorizados con una proyección practica más amplia encaminado al beneficio de estudiantes que se hallen interesados en investigar al memristor como nueva tecnología