A physical memristor based Muthuswamy–Chua–Ginoux system

Ginoux, Jean-Marc; Muthuswamy, Bharathwaj; Meucci, R.; Euzzor, Stefano; Garbo, Angelo Di; Kaliyaperumal, Ganesan

doi:10.1038/s41598-020-76108-z

Cited by 25 publications

(18 citation statements)

References 25 publications

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“…Moreover, it can be shown that for all g satisfying ( 11) the EP at the origin has unique unstable eigenvalue (see Appendix). This implies that for each fixed gap g ∈ (g a , g b ), and hence for the value of G a given by (10), there exists a range of g defined by condition (11) where SMCC possesses three EPs and the EP at the origin has a unique unstable eigenvalue. It is worth to remark that this scenario is quite similar to that displayed by the double-scroll family [44].…”

Section: B Nonlinearity Nmentioning

confidence: 99%

“…In the volatile case, to obtain oscillations, a passive memristor with an S-type locally active quasi-static i − v characteristic is used. As in a typical Hanson-Pearson oscillator, the memristor is biased via a suitable network in the locally-active region, i.e., in a branch of the characteristic with a negative differential resistance (NDR) [5], [6], [11], [12], [33]. It is worth to remark that NDR is observed in thermistors and other specific types of passive nanoscale devices, as NbO x , VO 2 , and TaO x devices [34].…”

Section: Introductionmentioning

confidence: 99%

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Oscillatory Circuits With a Real Non-Volatile Stanford Memristor Model

et al. 2022

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Stanford memristor model is a widely used model that accurately characterizes real nonvolatile metal-oxide resistive random access memory (RRAM) devices with bipolar switching characteristics. The paper studies for the first time the dynamics and bifurcations in a class of nonlinear oscillators with real non-volatile memristor devices obeying Stanford model. This is in contrast with papers in the literature considering oscillators with ideal, abstract, or artificial memristor models, that are unable to describe physical memristors implemented in nanotechnology. One main new idea in the paper is to use the memristor as a programmable nonlinear resistor. Namely, two principal modes of operation are considered. 1) Analogue transient phase: the oscillator is designed so that in the transient oscillations the voltage on the memristor is below threshold, hence the main memristor state variable, i.e., the gap of the insulating material, is almost constant and the memristor behaves as a static nonlinear resistor. 2) Programming phase: the nonlinear characteristic of the memristor, which depends on the gap, can be changed via the application of voltages above threshold. The paper studies nonlinear oscillations in the transient phase for a fixed gap as well as the bifurcations phenomena displayed when the gap is varied. The paper also discusses the differences between the approach in the paper and those to design other memristor oscillators with nonvolatile memristors.INDEX TERMS Bifurcations, Chua's circuit, complex dynamics, memristor, Stanford model.

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Section: B Nonlinearity Nmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Oscillatory Circuits With a Real Non-Volatile Stanford Memristor Model

et al. 2022

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“…As a nonlinear locally-active device, S-type LAM is conceptually simple for building oscillating circuit without pure negative resistor, and the local active region renders the oscillating system capable to amplify extermely small fluctuation in energy. Therefore, S-type LAM is preferred over other memristor in the design of chaotic oscillator [35][36][37]. In Ref [30], Wang designed a S-type LAM-based chaotic oscillator by using a resistor, a capacitor and an inductor.…”

Section: Introductionmentioning

confidence: 99%

A S-Type Bistable Locally-Active Memristor and Its Application in Oscillator Circuit

Xie

et al. 2021

Preprint

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In this paper, a S-type memristor with tangent nonlinearity is proposed. The introduced memristor can generate two kinds of stable pinched hysteresis loops with initial conditions from two flanks of the initial critical point. The power-off plot verifies that the memristor is nonvolatile, and the DC V-I plot shows that the memristor is locally active with the locally-active region symmetrical about the origin. The equivalent circuit of the memristor, derived by small-signal analysis method, is used to study the dynamics near the operating point in the locally-active region. Owing to the bistable and locally-active properties and S-type DC V-I curve, this memristor is called S-type BLAM for short. Then, a new Wien-bridge oscillator circuit is designed by substituting one of its resistances with S-type BLAM. It find that the circuit system can produce chaotic oscillation and complex dynamic behavior, which is further confirmed by analog circuit experiment.

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“…14 There is also a lot of research on building chaotic systems and neural networks based on memristors. [15][16][17][18][19][20][21][22][23][24][25][26][27][28][29][30] For example, in 2008, it was derived that several nonlinear oscillators from Chua's oscillators by replacing Chua's diodes with memristors. 15 In 2012, delayed switching effect was used to control the switching of a memristor synapse between two neurons.…”

Section: ⅰ Introductionmentioning

confidence: 99%

“…25 A physical memristor based on the Muthuswamy-Chua chaotic system (circuit) was provided. 27 In this paper, based on the memristor-based transient chaotic neural network (MTCNN), 31 the chaotic state for a long time is realized by the MTCNN. By MTCNN, AES initial key is dynamically generated to realize "one time one secret."…”

Section: ⅰ Introductionmentioning

confidence: 99%

A Dynamic AES Encryption Based on Memristive Chaos Neural Network

Liu

Chen

et al. 2021

Preprint

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This paper proposes an Advanced Encryption Standard (AES) encryption technique based on memristive neural network. A memristive chaotic neural network is constructed by the use of the nonlinear characteristics of the memristor. The chaotic sequence, which is sensitive to the initial value and has good random characteristics, is used as the initial key of AES grouping to realize "one-time-one-secret" dynamic encryption. Results show that the algorithm has higher security, larger key space and stronger robustness than the conventional AES. It can effectively resist the initial key fixed and exhaustive attacks.

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A physical memristor based Muthuswamy–Chua–Ginoux system

Cited by 25 publications

References 25 publications

Oscillatory Circuits With a Real Non-Volatile Stanford Memristor Model

Oscillatory Circuits With a Real Non-Volatile Stanford Memristor Model

A S-Type Bistable Locally-Active Memristor and Its Application in Oscillator Circuit

A Dynamic AES Encryption Based on Memristive Chaos Neural Network

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