Title :
An advanced no-snapback LDMOSFET with optimized breakdown characteristics of drain n-n+ diodes
Author :
Kawamoto, Kazunori ; Takahashi, Shigeki
Author_Institution :
Device R & D, DENSO Corp., Aichi, Japan
Abstract :
Snapbacks in sustain characteristics of lateral double-diffused MOSFETs (LDMOSFETs) are caused by positive feedbacks between the turn-on of the bipolar junction transistors (BJTs) and the avalanche breakdown of the drain n-n+ diodes . Although the n-n+ diodes are thus one of the most basic parasitic devices, which play a leading role in the snapback characteristics, neither a textbook nor a paper has ever described their breakdown characteristics in depth so as to realize a simple no-snapback LDMOSFET. This paper analyzes the snapback characteristics of n-n+ diodes and their mechanisms in detail. The no-snapback theory derived from this study is applied to an advanced no-snapback LDMOSFET with a simple structure, as an improved version of the conventional no-snapback LDMOSFET , which endures the electrostatic discharge (ESD) criterion for automotive applications: 15 kV, 150 pF, and 150 Ω.
Keywords :
MOSFET; bipolar transistors; electric breakdown; power integrated circuits; semiconductor diodes; automotive applications; avalanche breakdown; bipolar junction transistors; breakdown characteristics; current breakdown; drain n-n+ diodes; electrostatic discharge criterion; lateral double-diffused MOSFET; n-n+ diodes; no-snapback theory; parasitic devices; power integrated circuits; Automotive applications; Automotive engineering; Avalanche breakdown; Control systems; Diodes; Electric breakdown; Electrostatic discharge; Feedback; MOSFETs; Power integrated circuits; $hbox n-n^+$ junction; Current breakdown; ESD; electrostatic discharge; lateral double-diffused MOSFET; power integrated circuits;
Journal_Title :
Electron Devices, IEEE Transactions on
DOI :
10.1109/TED.2004.833591
