基于深度神经网络的初始静电电位分布生成

2019 International Conference on Simulation of Semiconductor Processes and Devices (SISPAD) Pub Date : 2019-09-01 DOI:10.1109/SISPAD.2019.8870521

Seung-Cheol Han, Sung-Min Hong

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引用次数: 4

摘要

训练深度神经网络来学习半导体器件的静电势。为了证明其可行性，我们考虑了pn二极管。制备了不同掺杂密度的pn二极管，并计算了数值解。所得到的静电电位分布在训练阶段使用。数值结果清楚地表明，所训练的神经网络能较好地提供初始静电势。由于改进了初始静电势，非线性泊松方程的Newton-Raphson环可以在更少的迭代次数内收敛。

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Deep Neural Network for Generation of the Initial Electrostatic Potential Profile

A deep neural network is trained to learn the electrostatic potential of the semiconductor device. In order to demonstrate its feasibility, pn diodes are considered. Various pn diodes with different doping densities are generated and the numerical solutions are calculated. The resultant electrostatic potential profiles are used in the training phase. Our numerical results clearly demonstrate that the trained neural network can provide the initial electrostatic potential reasonably well. Since the initial electrostatic potential is improved, the Newton-Raphson loop for the nonlinear Poisson equation can be converged within a smaller number of iterations.

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2019 International Conference on Simulation of Semiconductor Processes and Devices (SISPAD)

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