English

GEM: A GEneral Memristive Transistor Model

Applied Physics 2024-11-08 v2 Signal Processing

Abstract

Neuromorphic devices, with their distinct advantages in energy efficiency and parallel processing, are pivotal in advancing artificial intelligence applications. Among these devices, memristive transistors have attracted significant attention due to their superior stability and operation flexibility compared to two-terminal memristors. However, the lack of a robust model that accurately captures their complex electrical behavior has hindered further exploration of their potential. In this work, we introduce the GEneral Memristive transistor (GEM) model to address this challenge. The GEM model incorporates time-dependent differential equation, a voltage-controlled moving window function, and a nonlinear current output function, enabling precise representation of both switching and output characteristics in memristive transistors. Compared to previous models, the GEM model demonstrates a 300% improvement in modeling the switching behavior, while effectively capturing the inherent nonlinearities and physical limits of these devices. This advancement significantly enhances the realistic simulation of memristive transistors, thereby facilitating further exploration and application development.

Keywords

Cite

@article{arxiv.2408.15140,
  title  = {GEM: A GEneral Memristive Transistor Model},
  author = {Shengbo Wang and Jingfang Pei and Cong Li and Xuemeng Li and Li Tao and Arokia Nathan and Guohua Hu and Shuo Gao},
  journal= {arXiv preprint arXiv:2408.15140},
  year   = {2024}
}

Comments

5 pages, 5 figures

R2 v1 2026-06-28T18:25:34.614Z