AI‐assisted Field Plate Design of GaN HEMT Device

IF 2.9 4区 工程技术 Q1 MULTIDISCIPLINARY SCIENCES
Xiaofeng Xiang, Rafid Hassan Palash, Eiji Yagyu, Scott T. Dunham, Koon Hoo Teo, Nadim Chowdhury
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引用次数: 0

Abstract

GaN High Electron Mobility Transistors (HEMTs) plays a vital role in high‐power and high‐frequency electronics. Meeting the demanding performance requirements of these devices without compromising reliability is a challenging endeavor. Field Plates are employed to redistribute the electric field, minimizing the risk of device failure, especially in high‐voltage operations. While machine learning is applied to GaN device design, its application to field plate structures, known for their geometric complexity, is limited. This study introduces a novel approach to streamlining the field plate design process. It transforms complex 2D field plate structures into a concise feature space, reducing data requirements. A machine learning‐assisted design framework is proposed to optimize field plate structures and perform inverse design. This approach is not exclusive to the design of GaN HEMTs and can be extended to various semiconductor devices with field plate structures. The framework combines technology computer‐aided design (TCAD), machine learning, and optimization, streamlining the design process.
GaN HEMT 器件的人工智能辅助场板设计
氮化镓高电子迁移率晶体管(HEMT)在大功率和高频电子器件中发挥着至关重要的作用。要在不影响可靠性的前提下满足这些器件苛刻的性能要求,是一项极具挑战性的工作。场板用于重新分配电场,最大限度地降低器件失效的风险,尤其是在高压操作中。虽然机器学习已被应用于氮化镓器件设计,但其在以几何复杂性著称的场板结构上的应用还很有限。本研究介绍了一种简化场板设计流程的新方法。它将复杂的二维场板结构转化为简洁的特征空间,从而降低了数据要求。研究提出了一种机器学习辅助设计框架,用于优化场板结构和执行逆向设计。这种方法并不局限于氮化镓 HEMT 的设计,还可以扩展到各种具有场板结构的半导体器件。该框架结合了技术计算机辅助设计 (TCAD)、机器学习和优化,简化了设计流程。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
Advanced Theory and Simulations
Advanced Theory and Simulations Multidisciplinary-Multidisciplinary
CiteScore
5.50
自引率
3.00%
发文量
221
期刊介绍: Advanced Theory and Simulations is an interdisciplinary, international, English-language journal that publishes high-quality scientific results focusing on the development and application of theoretical methods, modeling and simulation approaches in all natural science and medicine areas, including: materials, chemistry, condensed matter physics engineering, energy life science, biology, medicine atmospheric/environmental science, climate science planetary science, astronomy, cosmology method development, numerical methods, statistics
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