神经形态工程学
编码(内存)
计算机科学
记忆电阻器
实现(概率)
人工智能
运动(物理)
仿生学
生物神经元模型
弹道
特征(语言学)
神经元
信息处理
生物运动
钥匙(锁)
人工神经元
电压
功能(生物学)
神经科学
机制(生物学)
计算机视觉
动力学(音乐)
人工神经网络
运动检测
作者
Xuerong Liu,Mengjie Shao,Xuetao Zhu,Lixun Wang,Hongwei Tan,Cong Hu,Yuejun Zhang,Run‐Wei Li
标识
DOI:10.1002/adma.202519352
摘要
Biological neurons are highly efficient in encoding motion information, and their physical realization can inspire the development of emerging bionic machine vision technologies for autonomous driving and video monitoring applications. However, due to the difficulty in emulating the complex ion movement dynamics within neurons, the use of hardware to comprehensively emulate neuronal firing dynamics for encoding function replication remains challenging. Herein, we report a bio-inspired artificial neuron based on a Cs2AgBiBr6 memristor, which can replicate both neuronal firing and refractory period behaviors for motion information processing. We demonstrate that the bidirectional migration of Ag+ and Br- ions within Cs2AgBiBr6 can induce threshold conductance switching along with a strong built-in internal electric potential, mimicking neuronal excitation-resting responses to voltage pulse stimuli. The artificial neurons can dynamically respond to continuous inputs from moving objects, encoding motion features (such as velocity, direction, and acceleration), into compressed feature maps for accurate classification and trajectory prediction. Our biomimetic encoding and prediction framework offers a promising strategy for developing neuromorphic systems with biologically realistic behaviors that may rival the capabilities of the human brain in processing complex dynamic information.
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