实现级联 GaN HEMT 开关噪声损耗折衷优化的 RC 缓冲器设计方法

IF 1.9 4区工程技术 Q3 ENGINEERING, ELECTRICAL & ELECTRONIC IET Power Electronics Pub Date : 2024-07-01 DOI:10.1049/pel2.12741

Peng Xue, Eckart Hoene, Pooya Davari

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摘要

级联氮化镓高电子迁移率晶体管（GaN HEMT）由于采用级联结构，非常容易产生自持关断振荡。本文提出了一种级联氮化镓 HEMT 的 RC 缓冲器设计方法，以实现优化的噪声损耗权衡。首先，本文提出了一个分析模型，用于描述基于级联 GaN HEMT 的测试电路利用 RC 缓冲器的不稳定性。在此模型的基础上，提出了实现两个最佳 RC 缓冲器设计 S1 和 S2 的分析方法。S1 设计能以最小的开关损耗令人满意地抑制振荡。设计 S2 能以最小的额外功率损耗成本实现最大的有效振荡阻尼。最后，通过双脉冲测试验证了所提模型的准确性，并获得了良好的一致性。

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An RC snubber design method to achieve optimized switching noise-loss trade-off of cascode GaN HEMTs

The cascode gallium nitride high electron mobility transistors (GaN HEMTs) are very vulnerable to self-sustained turn-off oscillation due to their cascode configuration. This paper presents a design approach for the RC snubber of cascode GaN HEMTs to achieve the optimized noise-loss trade-off. At first, an analytical model is proposed to describe the instability of cascode GaN HEMTs-based test circuits utilizing RC snubber. Based on the model, an analytical approach is proposed to achieve two optimum RC snubber designs S1 and S2. The design S1 can satisfactorily dampen the oscillation with minimum switching losses. The design S2 achieves maximum effective damping on the oscillation at a minimized cost of additional power losses. In the end, the accuracy of the proposed model is validated by the double-pulse test and good agreement is obtained.

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来源期刊

IET Power Electronics ENGINEERING, ELECTRICAL & ELECTRONIC-

CiteScore

5.50

自引率

10.00%

发文量

195

审稿时长

5.1 months

期刊介绍： IET Power Electronics aims to attract original research papers, short communications, review articles and power electronics related educational studies. The scope covers applications and technologies in the field of power electronics with special focus on cost-effective, efficient, power dense, environmental friendly and robust solutions, which includes: Applications: Electric drives/generators, renewable energy, industrial and consumable applications (including lighting, welding, heating, sub-sea applications, drilling and others), medical and military apparatus, utility applications, transport and space application, energy harvesting, telecommunications, energy storage management systems, home appliances. Technologies: Circuits: all type of converter topologies for low and high power applications including but not limited to: inverter, rectifier, dc/dc converter, power supplies, UPS, ac/ac converter, resonant converter, high frequency converter, hybrid converter, multilevel converter, power factor correction circuits and other advanced topologies. Components and Materials: switching devices and their control, inductors, sensors, transformers, capacitors, resistors, thermal management, filters, fuses and protection elements and other novel low-cost efficient components/materials. Control: techniques for controlling, analysing, modelling and/or simulation of power electronics circuits and complete power electronics systems. Design/Manufacturing/Testing: new multi-domain modelling, assembling and packaging technologies, advanced testing techniques. Environmental Impact: Electromagnetic Interference (EMI) reduction techniques, Electromagnetic Compatibility (EMC), limiting acoustic noise and vibration, recycling techniques, use of non-rare material. Education: teaching methods, programme and course design, use of technology in power electronics teaching, virtual laboratory and e-learning and fields within the scope of interest. Special Issues. Current Call for papers: Harmonic Mitigation Techniques and Grid Robustness in Power Electronic-Based Power Systems - https://digital-library.theiet.org/files/IET_PEL_CFP_HMTGRPEPS.pdf