Quantitative measure of hysteresis for memristors through explicit dynamics

Georgiou, Panayiotis S.; Yaliraki, Sophia N.; Drakakis, Emmanuel M.; Barahona, Mauricio

doi:10.1098/rspa.2011.0585

Cited by 27 publications

(45 citation statements)

References 37 publications

(84 reference statements)

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“…An ideal memristor , as defined originally by Chua , is characterised by a unique and time‐invariant q − φ function with the following properties : and on the i − υ plane its canonical form is obtained from and . Under these conditions, the charge‐controlled

\hat{q} ((), φ)

and flux‐controlled

\hat{φ} ((), q)

functions are invertible, and these two representations of the memristor are equivalent .…”

Section: Memristors and Memristive Systemsmentioning

confidence: 99%

Window functions and sigmoidal behaviour of memristive systems

Georgiou

Yaliraki

Drakakis

et al. 2016

Circuit Theory & Apps

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A common approach to model memristive systems is to include empirical window functions to describe edge effects and non-linearities in the change of the memristance. We demonstrate that under quite general conditions, each window function can be associated with a sigmoidal curve relating the normalised time-dependent memristance to the time integral of the input. Conversely, this explicit relation allows us to derive window functions suitable for the mesoscopic modelling of memristive systems from a variety of well-known sigmoidals. Such sigmoidal curves are defined in terms of measured variables and can thus be extracted from input and output signals of a device and then transformed to its corresponding window. We also introduce a new generalised window function that allows the flexible modelling of asymmetric edge effects in a simple manner.

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\hat{q} ((), φ)

and flux‐controlled

\hat{φ} ((), q)

functions are invertible, and these two representations of the memristor are equivalent .…”

Section: Memristors and Memristive Systemsmentioning

confidence: 99%

Window functions and sigmoidal behaviour of memristive systems

Georgiou

Yaliraki

Drakakis

et al. 2016

Circuit Theory & Apps

Self Cite

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“…As the theory stands in [3], w acts unphysically at the boundaries, this effect is corrected and nonlinearities are introduced at the device boundaries by the addition of window functions (see for example [9]- [11]). Most theoretical research has concentrated on using either Chua's theory [1], [12], Strukov's model [3] or an extension of it [13], although there has been some work in extending the model to a quantum domain [14]. In this paper, we will derive a novel description of the Strukov memristor by considering the electromagnetics of a uniform field across the whole device.…”

Section: Introductionmentioning

confidence: 98%

The Memory-Conservation Theory of Memristance

Gale

2014

2014 UKSim-AMSS 16th International Conference on Computer Modelling and Simulation

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The memristor, the recently discovered fundamental circuit element, is of great interest for neuromorphic computing, nonlinear electronics and computer memory. It is usually modelled either using Chua's equations, which lack material device properties, or using Strukov's phenomenological model (or models derived from it), which deviates from Chua's definitions due to the lack of a magnetic flux term. It is shown that by modelling the magnetostatics of the memory-holding ionic current (oxygen vacancies in the Strukov memristor), the memristor's magnetic flux can be identified as the flux arising from the ions. This leads to a novel theory of memristance consisting of two components: 1. A memory function which describes how the memristance, as felt by the ions, affects the conducting electrons located in the 'on' part of the device; 2. A conservation function which describes the time-varying resistance in the 'off' part of the device. This model allows for a straight-forward incorporation of the ions within the electronic theory and relates Chua's constitutive definition of a memristor with device material properties for the first time.

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“…The analyses are conducted by Cadence Spectre simulations. The memristor model developed by Strukov et al which assumes linear ionic drift is used to model both the current‐driven and voltage‐driven memristors. We expect that the circuits will be robust to thermal noise based on calculations which show that noise current will be much smaller compared with excitation currents and based on previous studies on noise analysis with memristors demonstrating robustness to noise .…”

Section: Introductionmentioning

confidence: 99%

Current‐input current‐output analog half center oscillator and central pattern generator circuits with memristors

Koymen

Drakakis

2018

Circuit Theory & Apps

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Summary The comparison of the memristor to the biological synapse has motivated the introduction of memristors to biomimetic circuits such as Central Pattern Generators (CPGs) and Half Center Oscillators (HCOs). The effects of the utilization of memristors in such systems have been investigated in this work. The HCO is a neural oscillator, and the CPG is made up of 4 HCOs producing oscillations corresponding to the locomotion of a 4‐limbed animal. Analog HCO and CPG circuits have been simulated using the Cadence Virtuoso platform and effects of using current‐driven and voltage‐driven memristors in different configurations with different parameters have been analyzed. Improvement in the stability of rhythm and variations in oscillation amplitudes have been observed.

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Quantitative measure of hysteresis for memristors through explicit dynamics

Cited by 27 publications

References 37 publications

Window functions and sigmoidal behaviour of memristive systems

Window functions and sigmoidal behaviour of memristive systems

The Memory-Conservation Theory of Memristance

Current‐input current‐output analog half center oscillator and central pattern generator circuits with memristors

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