Lintu Rajan, Arathy Varghese, C. Periasamy, V. Sahula
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引用次数: 0
摘要
利用机器学习方法探索氧化锌(ZnO)薄膜肖特基二极管氢传感器的设计空间,对器件设计优化进行了有效的尝试。我们采用最小二乘支持向量机(LS-SVM)建立回归模型来预测ZnO薄膜肖特基二极管氢传感器的输出行为。来自SILVACO international的ATLAS软件包已用于生成训练机器学习模型所需的数据集。计算了在较宽温度范围(300 K ~ 575 K)和ZnO薄膜厚度范围(5 nm ~ 300 nm)下氢致势垒高度的变化(Δϕb),并将其用于训练回归模型。研究结果表明,本文提出的建模方案可为氢传感用ZnO薄膜肖特基二极管的制作提供指导。
Device Design Space Exploration of Thin Film Hydrogen Sensor Based on Macro-model Generated Using Machine Learning
An efficient attempt has been performed towards device design optimization, using machine learning approach for exploration of design space of zinc oxide (ZnO) thin film Schottky diode based hydrogen sensor. We have adopted Least Square Support Vector Machine (LS-SVM) to build the regression model to predict the output behavior of ZnO thin film Schottky diode based hydrogen sensors. ATLAS package from SILVACO international has been used for generating data set, that is required to train the machine learning model. The hydrogen induced barrier height variations (Δϕb) at a wide range of temperature (300 K to 575 K) and wide range of ZnO thin film thickness (5 nm to 300 nm) have been calculated, which was used used for training the regression model. It has been observed that the proposed modeling scheme can serve a guide for fabrication of ZnO thin film based Schottky diode for hydrogen sensing applications.
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