Mathematical and Circuit Level Analysis Interpretation and Recommendations on Neuron Models

Sheriff, I. Munavar; Sakthivel, R.

doi:10.1142/s0218126622300082

J CIRCUIT SYST COMP

2022

DOI: 10.1142/s0218126622300082

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Mathematical and Circuit Level Analysis Interpretation and Recommendations on Neuron Models

I. Munavar Sheriff

R. Sakthivel

Abstract: Contrary to von Neumann computer architecture, neuromorphic computing is a biologically inspired method for building several sorts of brain-inspired computers. This computer technology uses silicon neurons and synapses to solve difficult machine learning and AI challenges. The goal of neuromorphic computing is to build a brain-like ability to compute, learn, and adapt. Building an appropriate neuroscience model, establishing a new architecture, modeling new devices, finding new materials for the devices, progr… Show more

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2024

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Cited by 3 publications

References 88 publications

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Mimic the electric activity in a heat-sensitive membrane in circuit

Jia,

Zhou,

Zhang

et al. 2024

AEU - International Journal of Electronics and Communications

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Mimic the electric activity in a heat-sensitive membrane in circuit

Jia,

Zhou,

Zhang

et al. 2024

AEU - International Journal of Electronics and Communications

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Generalized Bio-Plausible Neuron Model with Refractoriness, Frequency Adaptation and Dynamic Threshold

Sheriff,

Sakthivel

2024

J CIRCUIT SYST COMP

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Real biological neurons are dynamical systems that can process a nonlinear, arbitrary input signal with a dynamic threshold voltage, exhibit refractory time, and have a smooth [Formula: see text]–[Formula: see text] curve. This paper presents a generalized bio-plausible neuron model with refractoriness, frequency adaptation, and dynamic threshold. The spiking characteristics of the generalized neuron are enhanced with less circuitry and fewer parameters compared to older circuits. The proposed silicon neuron can generate all known spiking behaviors, just like a biological neuron. The circuit is designed using a 180[Formula: see text]nm standard CMOS process. The entire design uses 22 transistors with a total power consumption of only 2[Formula: see text]nW for a 1[Formula: see text]nA step current at a spike frequency of 122[Formula: see text]Hz. The power consumption and spike frequency rate depend on the input current. The proposed neuron is also capable of displaying both Type I and Type II frequency response characteristics. In addition, our neuron model underwent Monte Carlo simulation with 1000 sample runs to assess its robustness and stability against process variations and uncertainties. The results indicate that the average energy consumption of the proposed neuron model falls within the range of 16[Formula: see text]pJ to 68[Formula: see text]pJ.

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Computational Analysis of Self-Healing in Nanomaterials Using Neural Spike Algorithms

Seol,

Kim,

Kancharla

2024

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This computational study investigates dynamic self-healing processes in nanomaterials driven by neuronal spike activity. We developed a multiscale simulation framework that integrates neuronal dynamics, quantum mechanical effects, and material science principles. Our model incorporates a time-dependent neuron spike voltage equation coupled with a nanomaterial health update function, including quantum probability terms, to capture nanoscale effects. We employ reliability engineering concepts to assess system performance. Simulations reveal that neuronal spike patterns significantly influence self-healing dynamics, exhibiting non-linear behavior with quantum effects crucial to healing efficiency. Statistical analysis demonstrates a strong correlation between spike frequency and healing rate, identifying an optimal range for maximum recovery. Integrating quantum probabilities yields more accurate nanoscale behavior predictions than classical approaches alone. This study provides a foundation for understanding and optimizing neuronal spike-induced recovery in nanomaterials with potential applications in neural interfaces, intelligent materials, and biomedical devices.

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Mathematical and Circuit Level Analysis Interpretation and Recommendations on Neuron Models

Cited by 3 publications

References 88 publications

Mimic the electric activity in a heat-sensitive membrane in circuit

Mimic the electric activity in a heat-sensitive membrane in circuit

Generalized Bio-Plausible Neuron Model with Refractoriness, Frequency Adaptation and Dynamic Threshold

Computational Analysis of Self-Healing in Nanomaterials Using Neural Spike Algorithms

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