An interface device includes an NPN structure along a horizontal surface of a p-doped substrate. The NPN structure has a first n-doped region coupled to an output terminal, a p-doped region surrounding the first n-doped region and coupled to the output terminal, and a second n-doped region separated from the first n-doped region by the p-doped region. The interface device also includes a PNP structure along a vertical depth of the p-doped substrate. The PNP structure includes the p-doped region, an n-doped layer under the p-doped region, and the p-doped substrate. Advantageously, the interface device can withstand high voltage swing (both positive and negative), prevent sinking and sourcing large load current, and avoid entering into a low resistance mode during power down operations.

An integrated circuit includes an NMOS SCR in which a p-type body well of the NMOS transistor provides a base layer for a vertical NPN layer stack. The base layer is formed by implanting p-type dopants using an implant mask which has a cutout mask element over the base area, so as to block the p-type dopants from the base area. The base layer is implanted concurrently with p-type body wells under NMOS transistors in logic components in the integrated circuit. Subsequent anneals cause the p-type dopants to diffuse into the base area, forming a base with a lower doping density that adjacent regions of the body well of the NMOS transistor in the NMOS SCR. The NMOS SCR may have a symmetric transistor, a drain extended transistor, or may be a bidirectional NMOS SCR with a symmetric transistor integrated with a drain extended transistor.

A first silicon controlled rectifier has a breakdown voltage in a first direction and a breakdown voltage in a second direction. A second silicon controlled rectifier has a breakdown voltage with a higher magnitude than the first silicon controlled rectifier in the first direction, and a breakdown voltage with a lower magnitude than the first silicon controlled rectifier in the second direction. A bidirectional electrostatic discharge (ESD) structure utilizes both the first silicon controlled rectifier and the second silicon controlled rectifier to provide bidirectional protection.

An electrostatic discharge (ESD) protection device is disclosed including at least an NPN transistor and a PNP transistor coupled between a first node and a second node, wherein the ESD protection device may be configured to sink current from the first node to the second node in response to an ESD event. The transistors may be coupled such that a collector of the NPN may be coupled to the first node. A collector of the PNP may be coupled to the second node. A base of the NPN may be coupled to the emitter of the PNP. An emitter of the NPN may be coupled to a base of the PNP.

A silicon-controlled rectifier (SCR) includes a first-type field, a second-type first field and a second-type second field disconnectedly formed in a first-type well; an entire first-type doped region formed within the first-type field; a segmented second-type doped region formed within the second-type first field; and a segmented first-type doped region formed within the second-type second field.

An electrostatic discharge protection clamp includes a substrate and a first electrostatic discharge protection device over the substrate. The first electrostatic discharge protection device includes a buried layer over the substrate. The buried layer has a first region having a first doping concentration and a second region having a second doping concentration. The first doping concentration is greater than the second doping concentration. The first electrostatic discharge protection device includes a first transistor over the buried layer. The first transistor has an emitter coupled to a first cathode terminal of the electrostatic discharge protection clamp. The first electrostatic discharge protection device includes a second transistor over the buried layer. The second transistor has an emitter coupled to a first anode terminal of the electrostatic discharge protection clamp. A collector of the first transistor and a collector of the second transistor are over the first region of the buried layer.

Diffusion regions having the same conductivity type are arranged on a side of a second wiring and a side of a third wiring, respectively under a first wiring connected to a signal terminal. Diffusion regions are separated in a whole part or one part of a range in a Y direction. That is, under first wiring, diffusion regions are only formed in parts opposed to diffusion regions formed under the second wiring and third wiring connected to a power supply terminal or a ground terminal, and a diffusion region is not formed in a central part in an X direction. Therefore, terminal capacity of the signal terminal can be reduced without causing ESD resistance to be reduced, in an ESD protection circuit with the signal terminal.

An electrostatic discharge protection semiconductor device includes a substrate, a first well formed in the substrate, a second well formed in the substrate and spaced apart from the first well, a gate formed on the substrate and positioned in between the first well and the second well, a drain region formed in the first well, a source region formed in the second well, a first doped region formed in the first well and adjacent to the drain region, and a second doped region formed in the first well and spaced apart from both the first doped region and the gate. The first well, the drain region, and the source region include a first conductivity type, the second well, the first doped region and the second doped region include a second conductivity type, and the first conductivity type and the second conductivity type are complementary to each other.

Protection circuits and methods for protecting an integrated circuit against an over-limit electrical condition are provided. One example includes a snapback circuit having at least a portion formed in an isolated doped well region and configured to switch to a low impedance state in response to an input exceeding a trigger condition and further having a control circuit coupled to a reference voltage and further coupled to the isolated doped well region and the portion of the snapback circuit formed in the doped well region. The control circuit includes an impedance adjustable in response to a control signal and configured to adjust an isolated doped well impedance in which at least a portion of the snapback circuit is formed relative to the reference voltage. A modulated trigger and hold condition tot the snapback circuit can be set according to a control signal adjusting an electrical impedance of the control circuit.

An ESD protection device comprising an SCR-type circuit including a PNP transistor and NPN transistor incorporates a Zener diode which permits the circuit to operate at comparatively low trigger voltage thresholds. Zener diode breakdown voltage is controlled by doping levels in a doped area of an N-type well. One or more diodes connected in series between the SCR circuit and the input/output terminal of the device advantageously raises the snapback voltage of the SCR circuit. The use of nitride spacers between doped regions instead of gate oxide technology significantly reduces unwanted leakage currents.