• Title/Summary/Keyword: EDNMOS (Extended Drain N-type MOSFET)

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High Current Behavior and Double Snapback Mechanism Analysis of Gate Grounded Extended Drain NMOS Device for ESD Protection Device Application of DDIC Chip (DDIC 칩의 정전기 보호 소자로 적용되는 GG_EDNMOS 소자의 고전류 특성 및 더블 스냅백 메커니즘 분석)

  • Yang, Jun-Won;Kim, Hyung-Ho;Seo, Yong-Jin
    • Journal of Satellite, Information and Communications
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    • v.8 no.2
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    • pp.36-43
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    • 2013
  • In this study, the high current behaviors and double snapback mechanism of gate grounded_extended drain n-type MOSFET(GG_EDNMOS) device were analyzed in order to realize the robust electrostatic discharge(ESD) protection performances of high voltage operating display driver IC(DDIC) chips. Both the transmission line pulse(TLP) data and the thermal incorporated 2-dimensional simulation analysis as a function of ion implant conditions demonstrate a characteristic double snapback phenomenon after triggering of bipolar junction transistor(BJT) operation. Also, the background carrier density is proven to be a critical factor to affect the high current behavior of the GG_EDNMOS devices.

Improvements of Extended Drain NMOS (EDNMOS) Device for Electrostatic Discharge (ESD) Protection of High Voltage Operating LDI Chip (고전압용 LDI 칩의 정전기 보호를 위한 EDNMOS 소자의 특성 개선)

  • Yang, Jun-Won;Seo, Yong-Jin
    • Journal of Satellite, Information and Communications
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    • v.7 no.2
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    • pp.18-24
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    • 2012
  • High current behaviors of the extended drain n-type metal-oxide-semiconductor field effects transistor (EDNMOSFET) for electrostatic discharge (ESD) protection of high voltage operating LDI (LCD Driver IC) chip are analyzed. Both the transmission line pulse (TLP) data and the thermal incorporated 2-dimensional simulation analysis demonstrate a characteristic double snapback phenomenon after triggering of biploar junction transistor (BJT) operation. Also, background doping concentration (BDC) is proven to be a critical factor to affect the high current behavior of the EDNMOS devices. The EDNMOS device with low BDC suffers from strong snapback in the high current region, which results in poor ESD protection performance and high latchup risk. However, the strong snapback can be avoided in the EDNMOS device with high BDC. This implies that both the good ESD protection performance and the latchup immunity can be realized in terms of the EDNMOS by properly controlling its BDC.

Characteristics of Extended Drain N-type MOSFET with Double Polarity Source for Electrostatic Discharge Protection (정전기 보호를 위한 이중 극성소스를 갖는 EDNMOS 소자의 특성)

  • Seo, Yong-Jin;Kim, Kil-Ho;Park, Sung-Woo;Lee, Sung-Il;Han, Sang-Jun;Han, Sung-Min;Lee, Young-Keun;Lee, Woo-Sun
    • Proceedings of the KIEE Conference
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    • 2006.10a
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    • pp.97-98
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    • 2006
  • High current behaviors of extended drain n-type metal-oxide-semiconductor field effects transistor (EDNMOS) with double polarity source (DPS) for electrostatic discharge (ESD) protection are analyzed. Simulation based contour analyses reveal that combination of bipolar junction transistor operation and deep electron channeling induced by high electron injection gives rise to the second on-state. Therefore, the deep electron channel formation needs to be prevented in order to realize stable and robust ESD protection performance. Based on our analyses, general methodology to avoid the double snapback and to realize stable ESD protection is to be discussed.

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Improvement of ESD Protection Performance of High Voltage Operating EDNMOS Device with Double Polarity Source (DPS) Structure (DPS(Double Polarity Source) 구조를 갖는 고전압 동작용 EDNMOS 소자의 정전기 보호 성능 개선)

  • Seo, Yong-Jin;Yang, Jun-Won
    • Journal of Satellite, Information and Communications
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    • v.9 no.2
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    • pp.12-17
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    • 2014
  • In this paper, modified EDNMOS device with DPS (double polarity source) structure are suggested to realize stable and robust ESD (electrostatic discharge) protection performance of high voltage operating microchip. This DPS structure inserts the P+ diffusion layer on N+ source side, which in intended to block lateral extension of the electron rich region from N+ source side. Based on our simulation results, the inserted P+ diffusion layer effectively prevents the formation of deep electron channeling induced by high electron injection. As a result, our proposed DPS_EDNMOS devices could overcome the double snapback effect of conventional Std_EDNMOS device.