The impact of low-holding-voltage issue in high-voltage CMOS technology and the design of latchup-free power-rail ESD clamp circuit for LCD driver ICs

Ming-Dou Ker; Kun Hsien Lin

doi:10.1109/JSSC.2005.852046

The impact of low-holding-voltage issue in high-voltage CMOS technology and the design of latchup-free power-rail ESD clamp circuit for LCD driver ICs

Ming-Dou Ker^*, Kun Hsien Lin

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

47 Scopus citations

Abstract

The holding voltage of the high-voltage devices in snapback breakdown condition has been found to be much smaller than the power supply voltage. Such characteristics will cause the LCD driver ICs to be susceptible to the latchup-like danger in the practical system applications, especially while these devices are used in the power-rail ESD clamp circuit. A new latchup-free design on the power-rail ESD clamp circuit with stacked-field-oxide structure is proposed and successfully verified in a 0.25-μm 40-V CMOS process to achieve the desired ESD level. The total holding voltage of the stacked-field-oxide structure in snapback breakdown condition can be larger than the power supply voltage. Therefore, latchup or latchup-like issues can be avoided by stacked-field-oxide structures for the IC applications with power supply of 40 V.

Original language	English
Pages (from-to)	1751-1759
Number of pages	9
Journal	IEEE Journal of Solid-State Circuits
Volume	40
Issue number	8
DOIs	https://doi.org/10.1109/JSSC.2005.852046
State	Published - 1 Aug 2005

Keywords

Electrostatic discharge (ESD)
Latchup
Power-rail ESD clamp circuit
Transient latchup (TLU)
Transmission line pulsing (TLP)

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10.1109/JSSC.2005.852046

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title = "The impact of low-holding-voltage issue in high-voltage CMOS technology and the design of latchup-free power-rail ESD clamp circuit for LCD driver ICs",

abstract = "The holding voltage of the high-voltage devices in snapback breakdown condition has been found to be much smaller than the power supply voltage. Such characteristics will cause the LCD driver ICs to be susceptible to the latchup-like danger in the practical system applications, especially while these devices are used in the power-rail ESD clamp circuit. A new latchup-free design on the power-rail ESD clamp circuit with stacked-field-oxide structure is proposed and successfully verified in a 0.25-μm 40-V CMOS process to achieve the desired ESD level. The total holding voltage of the stacked-field-oxide structure in snapback breakdown condition can be larger than the power supply voltage. Therefore, latchup or latchup-like issues can be avoided by stacked-field-oxide structures for the IC applications with power supply of 40 V.",

keywords = "Electrostatic discharge (ESD), Latchup, Power-rail ESD clamp circuit, Transient latchup (TLU), Transmission line pulsing (TLP)",

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AB - The holding voltage of the high-voltage devices in snapback breakdown condition has been found to be much smaller than the power supply voltage. Such characteristics will cause the LCD driver ICs to be susceptible to the latchup-like danger in the practical system applications, especially while these devices are used in the power-rail ESD clamp circuit. A new latchup-free design on the power-rail ESD clamp circuit with stacked-field-oxide structure is proposed and successfully verified in a 0.25-μm 40-V CMOS process to achieve the desired ESD level. The total holding voltage of the stacked-field-oxide structure in snapback breakdown condition can be larger than the power supply voltage. Therefore, latchup or latchup-like issues can be avoided by stacked-field-oxide structures for the IC applications with power supply of 40 V.

KW - Electrostatic discharge (ESD)

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KW - Power-rail ESD clamp circuit

KW - Transient latchup (TLU)

KW - Transmission line pulsing (TLP)

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The impact of low-holding-voltage issue in high-voltage CMOS technology and the design of latchup-free power-rail ESD clamp circuit for LCD driver ICs

Abstract

Keywords

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