Thermal analytic model of current gain for bipolar junction transistor-bipolar static induction transistor compound device

Thermal analytic model of current gain for bipolar junction transistor-bipolar static induction transistor compound device

下载PDF

导出

摘要 This paper proposes a thermal analytical model of current gain for bipolar junction transistor-bipolar static induction transistor （BJT-BSIT） compound device in the low current operation. It also proposes a best thermal compensating factor to the compound device that indicates the relationship between the thermal variation rate of current gain and device structure. This is important for the design of compound device to be optimized. Finally, the analytical model is found to be in good agreement with numerical simulation and experimental results. The test results demonstrate that thermal variation rate of current gain is below 10% in 25 ℃-85 ℃ and 20% in -55 ℃-25 ℃. This paper proposes a thermal analytical model of current gain for bipolar junction transistor-bipolar static induction transistor （BJT-BSIT） compound device in the low current operation. It also proposes a best thermal compensating factor to the compound device that indicates the relationship between the thermal variation rate of current gain and device structure. This is important for the design of compound device to be optimized. Finally, the analytical model is found to be in good agreement with numerical simulation and experimental results. The test results demonstrate that thermal variation rate of current gain is below 10% in 25 ℃-85 ℃ and 20% in -55 ℃-25 ℃.

作者张有润张波李泽宏赖昌菁李肇基

机构地区 State Key Laboratory of Electronic Thin Films and Integrated Devices

出处《Chinese Physics B》 SCIE EI CAS CSCD 2009年第2期763-767,共5页 中国物理B（英文版）

关键词 bipolar junction transistor-bipolar static induction transistor thermal analytic model current gain bipolar junction transistor-bipolar static induction transistor, thermal analytic model current gain

分类号 TN32 [电子电信—物理电子学]

引文网络
相关文献

参考文献15

1Nenadovic N, d'Alessandro V, La Spina L, Rinald N and Nanver L K 2006 Electron Devices 53 643
2Shan X N and Huang R 2007 Acta Phys. Sin. 56 4943
3Nenadovic N, Nanver L K and Slotboom J W 2004 Electron Devices 51 2175
4Sheng K, Finney S J and Williams B W 2000 Industrial Electronics 47 9
5Nishizawa J I, Ohmi T and Chen H 1982 Electron Devices 29 1233
6Kang B W, Zhao W and Dong L M 1993 Electron Devices 40 1805
7Nakamura Y, Tadano H, Takigawa M, Igarashi I and Nishizawa J 1986 Electron Devices 33 810
8Kim C W, Kimura M, Yano K, Tanaka A and Sukegawa T 1990 Electron Devices 37 2070
9Giovanni Busatto 1993 IEEE Transactions on Power Electronics 8 368
10Salvatore Bellone 1985 Solid-State Electronics 28 317

1罗浩,向泽英,谢英英,罗晓琴.电位差计测热电偶电动势实验的拓展与应用[J].大学物理实验,2014,27(5):60-63. 被引量：7
2李兴冀,耿洪滨,兰慕杰,杨德庄,何世禹,刘超铭.Degradation mechanisms of current gain in NPN transistors[J].Chinese Physics B,2010,19(6):421-428. 被引量：2
3樊洁,宋小会,张殿琳.红外探测器TPS434低温、磁场性能研究[J].光谱学与光谱分析,2010,30(5):1153-1156. 被引量：1
4张有润,张波,李肇基,邓小川.Two-dimensional analysis of the interface state effect on current gain for a 4H-SiC bipolar junction transistor[J].Chinese Physics B,2010,19(6):453-458. 被引量：2
5廖亚非,张清文,何容盛.自有知识产权热流计的研究[J].重庆建筑大学学报,2006,28(1):105-107. 被引量：2
6廖亚非,张青文,何容盛.热流计的发展、国际领先技术与改进方向研究[J].重庆建筑大学学报,2005,27(2):84-87. 被引量：16
7张悦,李晓,王志斌.基于热电效应的痕量气体检测技术研究[J].中北大学学报（自然科学版）,2011,32(5):625-629. 被引量：2
8王鑫,董传帅,张晓凌,岳晓庆,何利民.空气-水段塞流冷却传热与相界面分布实验研究[J].中国科学院大学学报（中英文）,2017,34(2):232-236. 被引量：3
9沈丽,徐广臣,赵然,郭福.共晶二元Sn基焊料与Bi_2(Te_(0.9)Se_(0.1))_3基热电材料的界面反应[J].金属功能材料,2012,19(2):7-11. 被引量：2
10郑艺华,马永志.实验教学用简单量热计的研制[J].实验室研究与探索,2009,28(4):28-30.

Chinese Physics B

2009年第2期

浏览历史

内容加载中请稍等...

Thermal analytic model of current gain for bipolar junction transistor-bipolar static induction transistor compound device

参考文献15

相关作者

相关机构

相关主题

浏览历史