Abstract: A LDMOS device for an ESD protection circuit is provided. The LDMOS device includes a substrate of a first conductivity type, a deep well region of a second conductivity type, a body region of the first conductivity type, first and second doped regions of the second conductivity type, and a gate electrode. The deep well region is disposed in the substrate. The body region and the first doped region are respectively disposed in the deep well region. The second doped region is disposed in the body region. The gate electrode is disposed on the deep well region between the first and second doped regions. It is noted that the body region does not include a doped region of the first conductivity type having a different doped concentration from the body region.

Abstract: The invention relates to an electrostatic discharge protecting circuit with ultra-low standby leakage current for twice supply voltage tolerance. The electrostatic discharge protecting circuit of the invention includes a substrate driver, a third transistor, a start-up circuit, a RC circuit and a second resistor. The substrate driver has a first transistor and a second transistor in serious connection. The start-up circuit has a fourth transistor and a fifth transistor with diode-connected. The RC circuit has a first resistor, a sixth transistor and a seventh transistor in serious connection. Compared with the prior art, the electrostatic discharge protecting circuit with ultra-low standby leakage current for twice supply voltage tolerance of the invention with advantages of low standby leakage current, high ESD robustness, and no gate-oxide reliability issue is an excellent circuit solution for on-chip ESD protection design for mixed-voltage I/O buffers in nanometer CMOS technologies.

Abstract: An ESD protection device comprises a P-type substrate, a first substrate-triggered silicon controlled rectifiers (STSCR) disposed in the P-type substrate and a second STSCR disposed in the P-type substrate. The first STSCR comprises a first N-well, a first P-well, a first N+ diffusion region, a first P+ diffusion region, and a first trigger node. The second STSCR comprises a second N-well electrically connected to the first N-well, a second P-well electrically connected to the first P-well, a second N+ diffusion region electrically connected to the first P+ diffusion region, a second P+ diffusion region electrically connected to the first N+ diffusion region, and a second trigger node. A layout area of an integrated circuit and a pin-to-pin ESD current path can be reduced.

Abstract: An ESD protection device comprises a P-type substrate, a first substrate-triggered silicon controlled rectifiers (STSCR) disposed in the P-type substrate and a second STSCR disposed in the P-type substrate. The first STSCR comprises a first N-well, a first P-well, a first N+ diffusion region, a first P+ diffusion region, and a first trigger node. The second STSCR comprises a second N-well electrically connected to the first N-well, a second P-well electrically connected to the first P-well, a second N+ diffusion region electrically connected to the first P+ diffusion region, a second P+ diffusion region electrically connected to the first N+ diffusion region, and a second trigger node. A layout area of an integrated circuit and a pin-to-pin ESD current path can be reduced.

Abstract: Self-triggered Multi-finger SCRs used in ESD protection circuitry capable of turning on all SCR fingers of the multi-finger SCRs include a first source, a second source, N SCR units, (N?1) diodes, and N resistors. Each of the N SCR units includes a first node, a second node coupled to the second source, and a trigger node. An nth diode of the (N?1) diodes is coupled between a first node of an nth SCR unit and a trigger node of an (n+1)th SCR unit. An nth resistor is coupled between the first node of the nth SCR unit and the first source, wherein n and N are integers. The (N?1) diodes can be replaced by directly coupled the first node of the nth SCR unit to the trigger node of the (n+1)th SCR unit when a trigger pulse is applied at the trigger node of a first SCR unit.

Abstract: A LDMOS device includes a substrate of a first conductivity type, a deep well region of a second conductivity type, two body regions of the first conductivity type, a body connection region of the first conductivity type, two source regions of the second conductivity type, a drain region of the second conductivity type, a channel region, and a gate electrode. The body regions are disposed in the deep well region configured in the substrate. The body connection region is disposed in the deep well region to connect the body regions. Each of the source regions is disposed in the body region. The drain region is disposed in the deep well between the source regions. The channel region is disposed in a portion of the body region. The gate electrode is disposed on the deep well region between the source regions and the drain region and covers the channel region.

Abstract: A LDMOS device for an ESD protection circuit is provided. The LDMOS device includes a substrate of a first conductivity type, a deep well region of a second conductivity type, a body region of the first conductivity type, first and second doped regions of the second conductivity type, and a gate electrode. The deep well region is disposed in the substrate. The body region and the first doped region are respectively disposed in the deep well region. The second doped region is disposed in the body region. The gate electrode is disposed on the deep well region between the first and second doped regions. It is noted that the body region does not include a doped region of the first conductivity type having a different doped concentration from the body region.

Abstract: An ESD detection circuit which includes: a triggering circuit for generating an ESD trigger signal when the ESD detection circuit is in ESD mode; a bias circuit for providing at least a first bias voltage and a second bias voltage for controlling the operation of the triggering circuit; a trigger controlling circuit for decreasing a voltage difference between the first bias voltage and the second bias voltage when the ESD detection circuit is in the ESD mode, and for controlling a duration of the ESD trigger signal that is generated by the triggering circuit; and an activating control circuit for activating the trigger controlling circuit and the triggering circuit to enter the ESD mode according to a voltage level at a first node.

Abstract: A silicon controlled rectifier structure of polygonal layouts is provided. The polygonal first conductive type doped region is located in the middle of the polygonal second conductive type well. The first conductive type well shaped as a polygonal ring surrounds the second conductive type well and the second conductive type doped region is located within the first conductive type well and shaped as a polygonal ring concentric to the first conductive type well.

Abstract: A silicon controlled rectifier structure of polygonal layouts is provided. The polygonal first conductive type doped region is located in the middle of the polygonal second conductive type well. The first conductive type well shaped as a polygonal ring surrounds the second conductive type well and the second conductive type doped region is located within the first conductive type well and shaped as a polygonal ring concentric to the first conductive type well.

Abstract: An ESD detection circuit which includes: a triggering circuit for generating an ESD trigger signal when the ESD detection circuit is in ESD mode; a bias circuit for providing at least a first bias voltage and a second bias voltage for controlling the operation of the triggering circuit; a trigger controlling circuit for decreasing a voltage difference between the first bias voltage and the second bias voltage when the ESD detection circuit is in the ESD mode, and for controlling a duration of the ESD trigger signal that is generated by the triggering circuit; and an activating control circuit for activating the trigger controlling circuit and the triggering circuit to enter the ESD mode according to a voltage level at a first node.