A novel optimization design for 3.3 kV injection-enhanced gate transistor

This paper introduces a homemade injection-enhanced gate transistor (IEGT) with blocking voltage up to 3.7 kV. An advanced cell structure with dummy trench and a large cell pitch is adopted in the IEGT. The carrier concentration at the N-emitter side is increased by the larger cell pitch of the IEGT and it enhances the P-i-N effect within the device. The result shows that the IEGT has a remarkablely low on-state forward voltage drop (V_CE(sat)) compared to traditional trench IGBT structures. However, too large cell pitch decreases the channel density of the trench IEGT and increases the voltage drop across the channel, finally it will increase the V_CE(sat) of the IEGT. Therefore, the cell pitch selection is the key parameter consideration in the design of the IEGT. In this paper, a cell pitch selection method and the optimal value of 3.3 kV IEGT are presented by simulations and experimental results.     

SPTC~+-IGBT characteristics and optimization

A novel advanced soft punch through(SPT) IGBT signed as SPTC-IGBT is investigated.Static and dynamic characteristics are simulated based on the 1200 V device structure and adopted technology.Extensive research on the structure optimization of SPTC-IGBT is presented and discussed.Compared with the structure of conventional IGBT,SPTC-IGBT has a much lower collector-emitter saturation voltage and better switching characteristics.Therefore it is very suitable for applications blocking a voltage higher than 3000 V.In addition,due to the improvement of switching speed achieved by using a thinner chip,SPTC-IGBT is also very competitive in 1200 V and 1700 V applications.     

A novel optimization design for 3.3 kV injection-enhanced gate transisto

This paper introduces a homemade injection-enhanced gate transistor （IEGT） with blocking voltage up to 3.7 kV. An advanced cell structure with dummy trench and a large cell pitch is adopted in the IEGT. The carrier concentration at the N-emitter side is increased by the larger cell pitch of the IEGT and it enhances the P-i-N effect within the device. The result shows that the IEGT has a remarkablely low on-state forward voltage drop （VCE（sat）） compared to traditional trench IGBT structures. However, too large cell pitch decreases the channel density of the trench IEGT and increases the voltage drop across the channel, finally it will increase the VCE（sat） of the IEGT. Therefore, the cell pitch selection is the key parameter consideration in the design of the IEGT. In this paper, a cell pitch selection method and the optimal value of 3.3 kV IEGT are presented by simulations and experimental results.     

Trench SJ IGBT 的仿真研究

本文对沟槽型超结绝缘栅双极晶体管(trench SJ IGBT)进行了全面的分析,并通过Sentaurus TCAD仿真软件将其与沟槽型场截止绝缘栅双极晶体管(trench FS IGBT)进行了详尽的对比,仿真结果显示,在相同的条件下与trench FS IGBT 相比,trench SJ IGBT 的击穿电压提高了100 V,饱和导通压降降低了0.2 V,关断损耗减少了50%。最后,文章研究了电荷不平衡对trench SJ IGBT 的动静态参数的影响。对各参数和它们对电荷不平衡的灵敏度之间的折中进行了讨论。