Dynamical behavior of memristor-coupled heterogeneous discrete neural networks with synaptic crosstalk

Ma 马, Minglin 铭磷; Xiong 熊, Kangling 康灵; Li 李, Zhijun 志军; He 贺, Shaobo 少波

doi:10.1088/1674-1056/aceee9

Cited by 23 publications

(3 citation statements)

References 64 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…The parameters are as follows: b = 2, c = 7, d = 4, k = 5, m = 0.1, n = 0.01. The fractional-order system, denoted as (19), is characterized by an order of e = 0.7, with 20,000 iterations and a step size of 0.005, operating within the parameter range of [10,14]. The Lyapunov exponent spectrum, depicted in Figure 6a, shows that when a varies within the interval [10,11], the three lines consistently remain close to or below zero, indicating no positive Lyapunov exponents and positioning the system (19) in a periodic state.…”

Section: Dynamic Analysis Of the 5d Fomhsmentioning

confidence: 99%

“…Nonlinear science is theoretically significant and promising for practical applications across various life aspects. Over the past decade, researchers have extensively applied it in fields such as image encryption [1][2][3][4][5], electronic circuits [6][7][8][9][10], chaos synchronization [11][12][13][14][15], pseudo-random number generators [16][17][18][19][20], and neural networks [21][22][23][24][25], among others. The complex structure of chaotic attractors enhances their dynamic properties.…”

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Dynamic Analysis and Field-Programmable Gate Array Implementation of a 5D Fractional-Order Memristive Hyperchaotic System with Multiple Coexisting Attractors

Yu,

Zhang,

Xiao

et al. 2024

Fractal Fract

View full text Add to dashboard Cite

On the basis of the chaotic system proposed by Wang et al. in 2023, this paper constructs a 5D fractional-order memristive hyperchaotic system (FOMHS) with multiple coexisting attractors through coupling of magnetic control memristors and dimension expansion. Firstly, the divergence, Kaplan–Yorke dimension, and equilibrium stability of the chaotic model are studied. Subsequently, we explore the construction of the 5D FOMHS, introducing the definitions of the Caputo differential operator and the Riemann–Liouville integral operator and employing the Adomian resolving approach to decompose the linears, the nonlinears, and the constants of the system. The complex dynamic characteristics of the system are analyzed by phase diagrams, Lyapunov exponent spectra, time-domain diagrams, etc. Finally, the hardware circuit of the proposed 5D FOMHS is performed by FPGA, and its randomness is verified using the NIST tool.

show abstract

Section: Dynamic Analysis Of the 5d Fomhsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Dynamic Analysis and Field-Programmable Gate Array Implementation of a 5D Fractional-Order Memristive Hyperchaotic System with Multiple Coexisting Attractors

Yu,

Zhang,

Xiao

et al. 2024

Fractal Fract

View full text Add to dashboard Cite

show abstract

“…复杂、非易失存储及类神经突触可塑性等独特性质。因而，忆阻器是模拟生物神经突触的理想器件 [21][22][23][24] ，为人工神经网络的构建提供了新的思路。局部有源性被认为是动力系统复杂性的起源 [25] 。局部有源忆阻器能放大无限小能量振荡行为，应用于神经网络系统或神经元电路时易于诱发各类神经形态放电行为 [26] 。因此，利用局部有源忆阻器模拟生物神经突触受到越来越多的关注。将离散局部有源忆阻器引入人工神经网络或神经元，可以更准确地模拟生物神经元之间的电活动和信息传递，有助于揭示神经系统疾病的电生理学机制。文献 [27] 基于无离散忆阻器、离散忆阻器模拟电磁辐射刺激、离散局部有源忆阻器模拟生物突触等方式构建了三种离散神经网络模型；研究表明，离散忆阻器可使得神经网络模型产生更为复杂的混沌放电动力学行为。文献 [28]构建了一类离散忆阻 Rulkov 神经元模型，研究发现忆阻器可以有效地模拟离散神经元模型的磁感应效应。此外，文献 [29]研究了基于离散忆阻器的分数阶神经网络，发现其具有比整数阶神经网络更丰富的动力学行为。事实上，生物神经信息的处理和传递由不同脑区神经元的电磁活动共同完成，因此，探索异质离散神经网络的放电动力学和同步行为具有重要实际意义 [13] 。突触间的串扰由神经递质从一个突触溢出至另一个突触引起。突触神经递质的溢出将对相邻突触的连接强度产生干扰，因此，突触串扰将影响神经信号的放电及传输特性 [30,31] 。文献 [32]提出一种基于忆阻器突触的联想记忆电路，并研究了突触串扰对忆阻器功能的影响。文献 [33]揭示了不同串扰强度下，忆阻器耦合 HR 神经网络平衡点的数量和稳定性具有多样性。另外，越来越多的证据表明，突触串扰存在于多个不同大脑区域。例如，文献 [34]建立了一个异质神经网络，探讨了串扰强度对神经网络放电活动的影响，发现随着串扰强度的降低，异质神经元的放电行为从初始振荡逐渐过渡到完全同步。文献 [35]则从数值模拟角度探讨了串扰强度对异质离散神经网络放电行为和同步行为的影响。然而，目前尚没有关于突触串扰强度对神经网络共存放电行为影响的研究。事实上，共存放电意味着神经系统的不同等待状态 [36]…”

Section: 忆阻器被认为是除电阻、电容和电感之外的第四类无源电路元件，具有纳米尺寸、本征unclassified

Coexisting discharge and synchronization of heterogeneous discrete neural network with crosstalk memristor synapses

Wang,

Du,

et al. 2024

Acta Phys. Sin.

View full text Add to dashboard Cite

Synaptic crosstalk, which occurs due to the overflow of neurotransmitters between neighboring synapses, holds a crucial position in shaping the discharge characteristics and signal transmission within nervous systems. In this paper, two memristors are employed to simulate biological neural synapses and bidirectionally couple Chialvo discrete neuron and Rulkov discrete neuron. Thus, a heterogeneous discrete neural network with memristor-synapse coupling is constructed that takes into account the crosstalk behavior between memristor synapses in the coupled state. The analysis demonstrates that the quantity and stability of fixed points within this neural network intimately depend on the strength of synaptic crosstalk. Additionally, through a thorough investigation of bifurcation diagrams, phase diagrams, Lyapunov exponents, and time sequences, we uncover the multi-stable state property exhibited by the neural network. This property manifests in the coexistence of diverse discharge behaviors, which vary significantly with the synaptic crosstalk strength. Intriguingly, the introduction of control parameter to state variable triggers offset boosting and the emergence of infinite stable states within the neural network. Furthermore, we conducted a comprehensive study to explore the influence of synaptic crosstalk strength on the synchronization behavior of the neural network, considering various coupling strengths, initial conditions, and parameters. Our analysis, which was founded on the phase difference and synchronization factor of neuronal discharge sequences, revealed that the neural network maintains phase synchronization despite the variations of the two crosstalk strengths. The insights gained from this paper provide significant support in elucidating the electrophysiological mechanisms underlying biological neural information processing and transmission. Especially, the coexisting discharge phenomenon in the neural network provides an electrophysiological theoretical foundation for the clinical symptoms and diagnosis of the same neurological disease among different individuals or at different stages. And the doctors can predict the progression and prognosis of neurological disease based on the patterns and characteristics of coexisting discharge in patients, enabling them to adopt appropriate intervention measures and monitoring plans. Therefore, the research on coexisting discharge in the neural system contributes to the comprehensive treatment of nervous system disease.

show abstract

Electrical activity and synchronization of HR-tabu neuron network coupled by Chua Corsage Memristor

Li,

Wang,

et al. 2023

Nonlinear Dyn

View full text Add to dashboard Cite

show abstract

Dynamical behavior of memristor-coupled heterogeneous discrete neural networks with synaptic crosstalk

Cited by 23 publications

References 64 publications

Dynamic Analysis and Field-Programmable Gate Array Implementation of a 5D Fractional-Order Memristive Hyperchaotic System with Multiple Coexisting Attractors

Dynamic Analysis and Field-Programmable Gate Array Implementation of a 5D Fractional-Order Memristive Hyperchaotic System with Multiple Coexisting Attractors

Coexisting discharge and synchronization of heterogeneous discrete neural network with crosstalk memristor synapses

Electrical activity and synchronization of HR-tabu neuron network coupled by Chua Corsage Memristor

Contact Info

Product

Resources

About