神经形态工程学
光电子学
材料科学
异质结
计算机科学
冯·诺依曼建筑
图像处理
量子点
记忆电阻器
突触
砷化镓
RGB颜色模型
信号处理
人工神经网络
适应(眼睛)
逻辑门
计算机体系结构
纳米技术
晶体管
人工智能
图像传感器
建筑
并行处理
电子工程
CMOS芯片
计算机硬件
嵌入式系统
内存处理
机器视觉
等离子体子
作者
Zilong Guo,Z.W. Li,Q. W. Liu,ChunWei Zhang,J. H. Zhang,Hao Xuan Kan,Yang Li
标识
DOI:10.1109/ted.2025.3649620
摘要
In the fields of industrial manufacturing, biomedical diagnostics, and environmental monitoring, computing systems with von Neumann architecture suffer from inefficiencies due to the separation of UV sensing, memory, and processing, leading to increased complexity and hardware overhead. In-sensor computing utilizing UV-responsive optoelectronic neuromorphic devices offers a promising alternative by bypassing these limitations for efficient, low-power UV information processing. Here, we present a UV-responsive optoelectronic synapse based on a GaO x /ZnMgO quantum dots (QDs) heterojunction. This device selectively detects UV light and intrinsically suppresses noise, enabling integrated clear perception and fast computation. Various biological synaptic behaviors are demonstrated on the device under 300 nm UV illumination, including short-term memory (STM) to long-term memory (LTM) transition, learning–forgetting–relearning cycles, and dark adaptation behaviors. Leveraging synaptic features, a UV-driven neuromorphic vision system built from the device achieved 97% recognition accuracy on handwritten digits even in the presence of RGB noise. These results highlight the potential of GaO x /ZnMgO QDs heterojunction synapses for robust, noise-resilient in-sensor computing and high-fidelity UV image processing.
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