Memristor-Based Neural Network Circuit of Associative Memory With Overshadowing and Emotion Congruent Effect

被引：45

作者：

Sun, Junwei ^{[1
]}

Zhai, Yu ^{[1
]}

Liu, Peng ^{[1
]}

Wang, Yanfeng ^{[1
]}

机构：

[1] Zhengzhou Univ Light Ind, Sch Elect & Informat Engn, Zhengzhou 450002, Peoples R China

来源：

IEEE TRANSACTIONS ON NEURAL NETWORKS AND LEARNING SYSTEMS | 2025年 / 36卷 / 02期

基金：

中国国家自然科学基金;

关键词：

Associative memory; emotion congruent effect; memristor; neural network; overshadowing; GENERAL-MODEL; INFORMATION; BRAIN;

D O I：

10.1109/TNNLS.2023.3348553

中图分类号：

TP18 [人工智能理论];

学科分类号：

081104 ; 0812 ; 0835 ; 1405 ;

摘要：

Most memristor-based neural network circuits consider only a single pattern of overshadowing or emotion, but the relationship between overshadowing and emotion is ignored. In this article, a memristor-based neural network circuit of associative memory with overshadowing and emotion congruent effect is designed, and overshadowing under multiple emotions is taken into account. The designed circuit mainly consists of an emotion module, a memory module, an inhibition module, and a feedback module. The generation and recovery of different emotions are realized by the emotion module. The functions of overshadowing under different emotions and recovery from overshadowing are achieved by the inhibition module and the memory module. Finally, the blocking caused by long-term overshadowing is implemented by the feedback module. The proposed circuit can be applied to bionic emotional robots and offers some references for brain-like systems.

引用

页码：3618 / 3630

页数：13

共 49 条

[1] Yang S., Et al., BiCoSS: Toward large-scale cognition brain with multigranular neuromorphic architecture, IEEE Trans. Neural Netw. Learn. Syst., 33, 7, pp. 2801-2815, (2022)
[2] Song Y., Si J., Coleman S., Kerr D., Editorial biologically learned/inspired methods for sensing, control, and decision, IEEE Trans. Neural Netw. Learn. Syst., 33, 5, pp. 1820-1824, (2022)
[3] Zhang Z., Chen G., Yang S., Ensemble support vector recurrent neural network for brain signal detection, IEEE Trans. Neural Netw. Learn. Syst., 33, 11, pp. 6856-6866, (2022)
[4] Zhang A., Li X., Gao Y., Niu Y., Event-driven intrinsic plasticity for spiking convolutional neural networks, IEEE Trans. Neural Netw. Learn. Syst., 33, 5, pp. 1986-1995, (2022)
[5] Xing D., Li J., Zhang T., Xu B., A brain-inspired approach for collision-free movement planning in the small operational space, IEEE Trans. Neural Netw. Learn. Syst., 33, 5, pp. 2094-2105, (2022)
[6] Guo W., Yantir H.E., Fouda M.E., Eltawil A.M., Salama K.N., Toward the optimal design and FPGA implementation of spiking neural networks, IEEE Trans. Neural Netw. Learn. Syst., 33, 8, pp. 3988-4002, (2022)
[7] Ma J., Wang H., Qiao J., Adaptive neural fixed-time tracking control for high-order nonlinear systems, IEEE Trans. Neural Netw. Learn. Syst., 6, (2022)
[8] Wang H., Tong M., Zhao X., Niu B., Yang M., Predefined-time adaptive neural tracking control of switched nonlinear systems, IEEE Trans. Cybern., 53, 10, pp. 6538-6548, (2023)
[9] Zhang B., Guo Y., Li Y., He Y., Wang H., Dai Q., Memory recall: A simple neural network training framework against catastrophic forgetting, IEEE Trans. Neural Netw. Learn. Syst., 33, 5, pp. 2010-2022, (2022)
[10] Comsa I.-M., Potempa K., Versari L., Fischbacher T., Gesmundo A., Alakuijala J., Temporal coding in spiking neural networks with alpha synaptic function: Learning with backpropagation, IEEE Trans. Neural Netw. Learn. Syst., 33, 10, pp. 5939-5952, (2022)

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