Abstract: A semiconductor device includes a semiconductor-on-insulator (SOI) substrate having a bulk substrate layer, an active semiconductor layer and a buried insulator layer disposed between the bulk substrate layer and the active semiconductor layer. A trench is formed through the SOI substrate to expose the bulk substrate layer. A doped well is formed in an upper region of the bulk substrate layer adjacent trench. The semiconductor device further includes a first doped region different from the doped well that is formed in the trench.

Abstract: A diode string voltage adapter includes diodes formed in a substrate of a first conductive type. Each diode includes a deep well region of a second conductive type formed in the substrate. A first well region of the first conductive type formed on the deep well region. A first heavily doped region of the first conductive type formed on the first well region. A second heavily doped region of the second conductive type formed on the first well region. The diodes are serially coupled to each other. A first heavily doped region of a beginning diode is coupled to a first voltage. A second heavily doped region of each diode is coupled to a first heavily doped region of a next diode. A second heavily doped region of an ending diode provides a second voltage. The deep well region is configured to be electrically floated.

Abstract: Provided is a semiconductor device having high ESD tolerance. A first via (16) is used for electrically connecting a pad to a drain of an NMOS transistor of an ESD protection circuit. The first via (16) is arranged directly above the drain and present substantially directly under the pad. Consequently, a surge current caused by ESD and applied to the pad is more likely to flow uniformly among all the drains. Then, respective channels of the NMOS transistor of the ESD protection circuit are more likely to uniformly operate, and hence the ESD tolerance of the semiconductor device increases.

Abstract: Provided is a semiconductor device having high ESD tolerance. A first via (16) is used for electrically connecting a pad (22) to a drain of an NMOS transistor of an ESD protective circuit. The first vias (16) are formed under the pad (22) only on one side of a rectangular ring-shaped intermediate metal film (17) and on another side thereof opposed to the one side. In other words, all the first vias (16) for establishing an electrical connection to the drains are present substantially directly under the pad (22). Consequently, a surge current caused by ESD and applied to the pad (22) is more likely to flow uniformly among all the drains. Then, respective channels of the NMOS transistor of the ESD protective circuit are more likely to uniformly operate, and hence the ESD tolerance of the semiconductor device is increased.

Abstract: A semiconductor structure for facilitating an integration of power devices on a common substrate includes a first insulating layer formed on the substrate and an active region having a first conductivity type formed on at least a portion of the first insulating layer. A first terminal is formed on an upper surface of the structure and electrically connects with at least one other region having the first conductivity type formed in the active region. A buried well having a second conductivity type is formed in the active region and is coupled with a second terminal formed on the upper surface of the structure. The buried well and the active region form a clamping diode which positions a breakdown avalanche region between the buried well and the first terminal. A breakdown voltage of at least one of the power devices is a function of characteristics of the buried well.

Abstract: A semiconductor integrated circuit is provided. In the semiconductor integrated circuit, each of ESD protection circuitries is disposed between two of TSV bumps arrayed in a matrix, the two being arranged adjacent to each other. First main power lines are disposed to overlap P-channel ESD protection elements. Second main power lines are disposed to overlap N-channel ESD protection elements. The first and second main power lines are arranged orthogonally to each other.

Abstract: An electrostatic discharge protection clamp adapted to limit a voltage appearing across protected terminals of an integrated circuit to which the electrostatic discharge protection clamp is coupled is presented. The electrostatic discharge protection clamp includes a substrate, and a first electrostatic discharge protection device formed over the substrate. The first electrostatic discharge protection device includes a buried layer formed over the substrate, the buried layer having a first conductivity type and defining an opening located over a region of the substrate, a first transistor formed over the opening of the buried layer, the first transistor having an emitter coupled to a first cathode terminal of the electrostatic discharge protection clamp, and a second transistor formed over the buried layer, the second transistor having an emitter coupled to a first anode terminal of the electrostatic discharge protection clamp.

Abstract: 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.

Abstract: A semiconductor device includes a substrate having a first type doping. The semiconductor device further includes a first deep well in the substrate, the first deep well having a second type doping. The semiconductor device further includes a second deep well in the substrate, the second deep well having the second type doping and being separated and above the first deep well. The semiconductor device further includes a first well over the second deep well, the first well having the first type doping and a gate structure over the first well.

Abstract: A block power switch may be embedded with electrostatic discharge (ESD) protection circuitry. A transistor portion of the block power switch may be allocated to act as part of ESD protection circuitry and may be combined with an RC clamp to provide ESD protection. Adaptive body biasing (ABB) may be applied to the block power switch to reduce on-chip area and decrease leakage current of the block power switch.

Abstract: Embodiments of the invention provide increased ESD protection suitable for high-voltage devices. In one embodiment, an internal DMOS circuit is placed in parallel with a lateral NPN ESD clamp. The clamp has both a high holding voltage, above the operating voltage of the DMOS circuit, and a high maximum current before breakdown. The discharge path of the clamp includes a high-voltage lightly doped well containing a low-voltage higher doped well. The dopant of both wells is the same type, and the interface between the two defines a graded junction. The emitter of the entire circuit is grounded and the collector is coupled to the voltage of the DMOS circuit.

Abstract: The disclosure provides a switching device with a free-wheeling diode, including a switching tube; a heat radiating substrate is arranged on the drain electrode of the switching tube; the switching device further includes a heat radiating component, which is connected with the heat radiating substrate of the switching tube by contact; the free-wheeling diode is a compression joint type diode; the anode end face of the free-wheeling diode is abutted against the heat radiating component, and is electrically connected with the drain electrode of the switching tube via the heat radiating component, which not only realizes the heat radiation function by using the heat radiating component, but also realizes the electric connection to the heat radiating substrate by using the electrical conductivity of the heat radiating component.

Abstract: A device used as an ESD protection structure, which is a modified N-type LDMOS device is disclosed. A conventional LDMOS includes only one N-type heavily doped region as a drain in an N-type lightly doped region (11), while the device of the invention includes a P-type heavily doped region (22) in an N-type lightly doped region (11), dividing the N-type heavily doped region into two N-type heavily doped regions (21, 23) unconnected and independent to each other. The N-type heavily doped region (21) close to the gate (14) has no picking-up terminal. The N-type heavily doped region (23) away from the gate (14) together with the P-type heavily doped region (22) is picked up and connected to an input/output bonding pad.

Abstract: A semiconductor device includes a transistor having a gate electrode, a first electrode, and a second electrode and first and second protection circuits each having one end commonly connected to the gate electrode and the other end connected to the first and second electrodes, respectively. The first and second protection circuits are formed in first and second polysilicon layers, respectively, formed separately on a single field insulating film.

Abstract: An integrated circuit (IC) including a well region of the IC having a first doping level and a plurality of semiconductor regions implanted in the well region. Each of the plurality of semiconductor regions has a second doping level. The second doping level is greater than the first doping level. A plurality of polysilicon regions are arranged on the plurality of semiconductor regions. The polysilicon regions are respectively connected to the semiconductor regions. The plurality of semiconductor regions is a drain of a metal-oxide semiconductor field-effect transistor (MOSFET).

Abstract: Electro-static discharge (“ESD”) protection for a die of a multi-chip module is described. A contact has an externally exposed surface after formation of the die and prior to assembly of the multi-chip module. The contact is for a die-to-die interconnect of the multi-chip module. The contact is for an internal node of the multi-chip module after the assembly of the multi-chip module. A driver circuit is coupled to the contact and has a first input impedance. A discharge circuit is coupled to the contact for electrostatic discharge protection of the driver circuit and has a first forward bias impedance associated with a first discharge path. The first forward bias impedance is a fraction of the first input impedance.

Abstract: An electrostatic discharge (ESD) protection structure and an ESD protection circuit are provided. A PMOS transistor is located in a first region of a first N-type well region of a semiconductor substrate. A first doped base region located in a second region of a first N-type well region is N-type doped and connected to an external trigger-voltage adjustment circuit. An NMOS transistor is located in a third region of a first P-type well region. Second doped base regions discretely located in a fourth region of a first P-type well region are P-type doped and connected to the external trigger-voltage adjustment circuit. A first N-region is located in the fourth region, surrounding the second doped base regions, and connected to the I/O interface terminal. A second N-region is located in the fourth region, surrounding the first N-region and the second doped base regions, and connected to the ground terminal.

Abstract: One method disclosed herein includes forming first and second transistor devices in and above adjacent active regions that are separated by an isolation region, wherein the transistors comprise a source/drain region and a shared gate structure, forming a continuous conductive line that spans across the isolation region and contacts the source/drain regions of the transistors and etching the continuous conductive line to form separated first and second unitary conductive source/drain contact structures that contact the source/drain regions of the first and second transistors, respectively. A device disclosed herein includes a gate structure, source/drain regions, first and second unitary conductive source/drain contact structures, each of which contacts one of the source/drain regions, and first and second conductive vias that contact the first and second unitary conductive source/drain contact structures, respectively.

Abstract: An antifuse of a semiconductor device and a method of fabricating the same capable of causing an antifuse to stably operate by rupturing the antifuse at a specific point and stabilizing a current level when rupturing the antifuse are provided. The antifuse may include: a device isolation layer defining a first active region in a semiconductor substrate; a first and second junction regions provided in the first active region; a second active region formed over the first junction region; a gate insulating layer formed over the first active region and the second active region; and a gate electrode formed over the gate insulating layer.

Abstract: An integrated circuit including a first power rail, a second power rail, a power clamp connected between the first and second power rails; and a trigger circuit connected to the power clamp and the first second power rails. The trigger circuit includes an RC element formed on the basis of field effect transistors, first inverter stage connected to the RC element, a second inverter stage, and a third inverter stage. The first, second and third inverter stages are connected in series to a control input of the power clamp. The trigger circuit also included a feed back connection from an output of the second inverter stage to the first inverter stage.

Abstract: Various aspects provide for structures and devices to protect against spurious electrical events (e.g., electrostatic discharge). Some embodiments incorporate a voltage switchable dielectric material (VSDM) bridging a gap between two conductive pads. Normally insulating, the VSDM may conduct current from one pad to the other during a spurious electrical event (e.g., shunting current to ground). Some aspects include gaps having a gap width that is greater than 50% of a spacing between electrical leads connected to the pads. Some devices include single layers of VSDM. Some devices include multiple layers of VSDM. Various devices may be designed to increase a ratio of active volume (of VSDM) to inactive volume.

Abstract: A junction diode array is disclosed for use in protecting integrated circuits from electrostatic discharge. The junction diodes integrate symmetric and asymmetric junction diodes of various sizes and capabilities. Some of the junction diodes are configured to provide low voltage and current discharge via un-encapsulated interconnecting wires, while others are configured to provide high voltage and current discharge via encapsulated interconnecting wires. Junction diode array elements include p-n junction diodes and N+/N++ junction diodes. The junction diodes include implanted regions having customized shapes. If both symmetric and asymmetric diodes are not needed as components of the junction diode array, the array is configured with isolation regions between diodes of either type. Some junction diode arrays include a buried oxide layer to prevent diffusion of dopants into the substrate beyond a selected depth.

Abstract: A semiconductor device and a method for fabricating the semiconductor device. The device includes: a doped semiconductor having a source region, a drain region, a channel between the source and drain regions, and an extension region between the channel and each of the source and drain regions; a gate formed on the channel; and a screening coating on each of the extension regions. The screening coating includes: (i) an insulating layer that has a dielectric constant that is no greater than about half that of the extension regions and is formed directly on the extension regions, and (ii) a screening layer on the insulating layer, where the screening layer screens the dopant ionization potential in the extension regions to inhibit dopant deactivation.

Abstract: Semiconductor devices and methods of forming the same are provided. The semiconductor device may include a semiconductor element disposed on a substrate and including an insulating layer and a gate electrode, a doped region having a first conductivity-type on the substrate, a conductive interconnection electrically connected to the gate electrode, and a first contact plug having a second conductivity-type and electrically connecting the conductive interconnection and the doped region to each other and constituting a Zener diode by junction with the doped region.

Abstract: Methods and apparatus for increased holding voltage SCRs. A semiconductor device includes a semiconductor substrate of a first conductivity type; a first well of the first conductivity type; a second well of a second conductivity type adjacent to the first well, an intersection of the first well and the second well forming a p-n junction; a first diffused region of the first conductivity type formed at the first well and coupled to a ground terminal; a first diffused region of the second conductivity type formed at the first well; a second diffused region of the first conductivity type formed at the second well and coupled to a pad terminal; a second diffused region of the second conductivity type formed in the second well; and a Schottky junction formed adjacent to the first diffused region of the second conductivity type coupled to a ground terminal. Methods for forming devices are disclosed.

Abstract: A semiconductor ESD protection apparatus comprises a substrate; a first doped well disposed in the substrate and having a first conductivity; a first doped area having the first conductivity disposed in the first doped well; a second doped area having a second conductivity disposed in the first doped well; and an epitaxial layer disposed in the substrate, wherein the epitaxial layer has a third doped area with the first conductivity and a fourth doped area with the second conductivity separated from each other. Whereby a first bipolar junction transistor (BJT) equivalent circuit is formed between the first doped area, the first doped well and the third doped area; a second BJT equivalent circuit is formed between the second doped area, the first doped well and the fourth doped area; and the first BJT equivalent circuit and the second BJT equivalent circuit have different majority carriers.

Abstract: Protecting a gate dielectric is achieved with a gate dielectric protection circuit coupled to a transistor at risk. The protection circuit is activated to reduce the voltage across the gate dielectric (VDIFF) to below its breakdown voltage (VBD). The protection circuit is activated when an ESD event is detected. The protection circuit provides a protection or ESD bias to reduce VDIFF below VBD.

Abstract: A bi-directional electrostatic discharge (ESD) protection device may include a substrate, an N+ doped buried layer, an N-type well region and two P-type well regions. The N+ doped buried layer may be disposed proximate to the substrate. The N-type well region may encompass the two P-type well regions such that a portion of the N-type well region is interposed between the two P-type well regions. The P-type well regions may be disposed proximate to the N+ doped buried layer and comprise one or more N+ doped plates, one or more P+ doped plates, one or more field oxide (FOX) portions, and one or more field plates. A multi-emitter structure is also provided.

Abstract: This invention discloses a semiconductor power device that includes a plurality of power transistor cells surrounded by a trench opened in a semiconductor substrate. At least one of the cells constituting an active cell has a source region disposed next to a trenched gate electrically connecting to a gate pad and surrounding the cell. The trenched gate further has a bottom-shielding electrode filled with a gate material disposed below and insulated from the trenched gate. At least one of the cells constituting a source-contacting cell surrounded by the trench with a portion functioning as a source connecting trench is filled with the gate material for electrically connecting between the bottom-shielding electrode and a source metal disposed directly on top of the source connecting trench.

Abstract: A high voltage semiconductor switch includes a first field-effect transistor having a source, a drain and a gate, and being adapted for switching a voltage at a rated high-voltage level, the first field-effect transistor being a normally-off enhancement-mode transistor, a second field-effect transistor having a source, a drain and a gate, connected in series to the first field-effect transistor, the second field-effect transistor being a normally-on depletion-mode transistor; and a control unit connected to the drain of the first field-effect transistor and to the gate of the second field-effect transistor and being operable for blocking the second field-effect transistor if a drain-source voltage across the first field-effect transistor exceeds the rated high-voltage level.

Abstract: A representative electrostatic discharge (ESD) protection circuit includes a silicon-controlled rectifier comprising an alternating arrangement of a first P-type semiconductor material, a first N-type semiconductor material, a second P-type semiconductor material and a second N-type semiconductor material electrically coupled between an anode and a cathode. The anode is electrically coupled to the first P-type semiconductor material and the cathode is electrically coupled to the second N-type semiconductor material. The ESD protection circuit further includes an inductor electrically coupled between the anode and the second P-type semiconductor material or between the cathode and the first N-type semiconductor material.

Abstract: An ESD protection circuit including a substrate of a first conductivity type, an annular well region of a second conductivity type, two first regions of the first conductivity type and at least one transistor of the second conductivity type is provided. The annular well region is disposed in the substrate. The first regions are disposed in the substrate and surrounded by the annular well region. The at least one transistor is disposed on the substrate between the first regions and including a source, a gate, and a drain. The annular well region and the drain are coupled to a first voltage source. The source and one of the first regions are coupled to a second voltage source, and the other of the first regions is coupled to a substrate triggering circuit.

Abstract: An electrostatic discharge (ESD) protection circuit includes a first array of transistors, having source and drain doped with a first type of material, arranged in parallel in a first block, and a second array of transistors, having source and drain doped with the first type of material, arranged in parallel in a second block. The ESD protection circuit also includes an active region between the first and second array of transistors doped with a second type of material that is complementary to the first type of material.

Abstract: Apparatus and methods for precision mixed-signal electronic circuit protection are provided. In one embodiment, an apparatus includes a p-well, an n-well, a poly-active diode structure, a p-type active region, and an n-type active region. The poly-active diode structure is formed over the n-well, the p-type active region is formed in the n-well on a first side of the poly-active diode structure, and the n-type active region is formed along a boundary of the p-well and the n-well on a second side of the poly-active diode structure. During a transient electrical event the apparatus is configured to provide conduction paths through and underneath the poly-active diode structure to facilitate injection of carriers in the n-type active region. The protection device can further include another poly-active diode structure formed over the p-well to further enhance carrier injection into the n-type active region.

Abstract: Disclosed herein is an electrostatic discharge protection structure which includes a signal line, a thin-film transistor and a shunt wire. The thin-film transistor includes a gate electrode, a metal-oxide semiconductor layer, a source electrode and a drain electrode. The first metal-oxide semiconductor layer is disposed above the first gate electrode. The metal-oxide semiconductor layer has a channel region characterized in having a width/length ratio of less than 1. The source electrode is equipotentially connected to the gate electrode. The shunt wire is electrically connected to the drain electrode. When the signal line receives a voltage surge of greater than a predetermined magnitude, the voltage surge is shunted through the thin-film transistor to the shunt wire.

Abstract: An electrostatic discharge (ESD) protection element includes a collector area, a first barrier area, a semiconductor area, a second barrier area and an emitter area. The collector area has a first conductivity type. The first barrier area borders on the collector area and has a second conductivity type. The semiconductor area borders on the first barrier area and is an intrinsic semiconductor area, or has the first or second conductivity type and a dopant concentration which is lower than a dopant concentration of the first barrier area. The second barrier area borders on the semiconductor area and has the second conductivity type and a higher dopant concentration than the semiconductor area. The emitter area borders on the second barrier area and has the first conductivity type.

Abstract: A standard cell has gate patterns extending in Y direction and arranged at an equal pitch in X direction. End portions of the gate patterns are located at the same position in Y direction, and have an equal width in X direction. A diode cell is located next to the standard cell in Y direction, and includes a plurality of opposite end portions formed of gate patterns that are opposed to the end portions, in addition to a diffusion layer which functions as a diode.

Abstract: A semiconductor substrate (1) is provided with a source region (2) and a drain region (3) of a first type of electrical conductivity arranged at a surface (10) at a distance from one another, a channel region (4) of a second type of electrical conductivity, which is opposite to the first type of electrical conductivity, arranged between the source region (2) and the drain region (3), and a gate electrode (6) arranged above the channel region (4). A substrate well (7) of the first type of electrical conductivity is arranged in the substrate (1) at a distance from the source region (2). The substrate well (7) is contiguous with the drain region (3), and the distance between the source region (2) and the substrate well (7) is larger than the distance between the source region (2) and the drain region (3).

Abstract: An integrated circuit with a shallow trench isolated, low capacitance, ESD protection diode. An integrated circuit with a gate space isolated, low capacitance, ESD protection diode. An integrated circuit with a gate space isolated, low capacitance, ESD protection diode in parallel with a shallow trench isolated, low capacitance, ESD protection diode.

Abstract: An electrostatic discharge (ESD) protection circuit includes a triggering diode that includes a junction between a P-grade (PG) region and an N-well. The PG region has a dopant profile equivalent to a P-drain dopant profile of a PMOS transistor having a breakdown voltage represented by V whereby the triggering diode for conducting a current when a voltage greater than the breakdown voltage V is applied. In an exemplary embodiment, the dopant profile of the PG region includes two dopant implant profiles that include a shallow implant profile with a higher dopant concentration and a deep implant profile with a lower dopant concentration.

Abstract: A semiconductor device is disclosed with a protection device formed of a parasitic bipolar transistor, a parasitic diode and a parasitic resistance and operated at a lowered operating voltage to be capable of improving a blocking capability against an over voltage. The impurity concentration in a semiconductor layer as the base of a parasitic bipolar transistor is lower compared with the impurity concentration of a semiconductor layer of the same conduction type arranged adjacently to the semiconductor layer as the base and to be the anode of a parasitic diode. The lowered impurity concentration is determined to be the concentration for making the parasitic bipolar transistor have a snapback phenomenon occur.

Abstract: An integrated circuit with a shallow trench isolated, low capacitance, ESD protection diode. An integrated circuit with a gate space isolated, low capacitance, ESD protection diode. An integrated circuit with a gate space isolated, low capacitance, ESD protection diode in parallel with a shallow trench isolated, low capacitance, ESD protection diode.

Abstract: Apparatus and methods for electronic circuit protection are disclosed. In one embodiment, an apparatus comprises a well having an emitter and a collector region. The well has a doping of a first type, and the emitter and collector regions have a doping of a second type. The emitter region, well, and collector region are configured to operate as an emitter, base, and collector for a first transistor, respectively. The collector region is spaced away from the emitter region to define a spacing. A first spacer and a second spacer are positioned adjacent the well between the emitter and the collector. A conductive plate is positioned adjacent the well and between the first spacer and the second spacer, and a doping adjacent the first spacer, the second spacer, and the plate consists essentially of the first type.

Abstract: A semiconductor device is disclosed, which includes first and second power supply pads supplied with first and second power voltages, respectively, a first protection circuit coupled between the first and second power supply pads, and an internal circuit including a first power line and a plurality of transistors electrically coupled to the first power line. The first power line includes first and second portions, and the first portion is electrically connected to the first power supply pad. The device further includes a second protection circuit coupled between the second portion of the first power line and the second power supply pad.

Abstract: A semiconductor device, including a substrate having an active region defined therein, a plurality of bit lines extending on the substrate in a first direction, a plurality of interconnection lines extending on the substrate in a second direction, a pad electrically connected to the plurality of interconnection lines and configured to apply an external voltage, a plurality of metal contacts electrically connecting the interconnection lines and the plurality of bit lines, and a plurality of bit line contacts that are in contact with the active region and electrically connect the plurality of bit lines and the active region, wherein a size of at least some of the bit line contacts and/or at least some of the metal contacts vary based on a distance of the respective bit line contact or the metal contact from the pad.

Abstract: Methods for opening polysilicon NFET and PFET gates for a replacement gate process are disclosed. Embodiments include providing a polysilicon gate with a nitride cap; defining PFET and NFET regions of the polysilicon gate, creating a nitride bump on the nitride cap; covering the nitride cap to a top of the nitride bump with a PMD; performing a 1:1 dry etch of the PMD and the nitride bump; and performing a second dry etch, selective to the nitride cap, down to the top surface of the polysilicon gate. Other embodiments include, after creating a nitride bump on the nitride cap, recessing the PMD to expose the nitride cap; covering the nitride cap and the nitride bump with a nitride fill, forming a planar nitride surface; and removing the nitride fill, nitride bump, and nitride cap down to the polysilicon gate.

Abstract: An ESD protection device, which is arranged to be active at a triggering voltage (Vt1) for providing ESD protection, comprises a first region of the first conductivity type formed in a semiconductor layer of the first conductivity type, the first region extending from a surface of the semiconductor layer and being coupled to a first current electrode (C) of the semiconductor device, a well region of a second conductivity type formed in the semiconductor layer extending from the surface of the semiconductor layer, and a second region of the second conductivity type formed in the well region, the second region being coupled to a second current electrode (B). The ESD protection device further comprises a floating region of the second conductivity type formed in the semiconductor layer between the first current electrode (C) and the well region and extending from the surface of the semiconductor layer a predetermined depth.

Abstract: Methods are provided for producing stacked electrostatic discharge (ESD) clamps. In one embodiment, the method includes providing a semiconductor substrate in which first and second serially-coupled transistors are formed. The first transistor includes a first well region having a first lateral edge partially forming the first transistor's base. The second transistor including a second well region having a second lateral edge partially forming the second transistor's base. Third and fourth well regions are formed in the first and second transistors, respectively, and extend a different distance into the substrate than do the well regions of the first and second transistors. The third well region has a third lateral edge separated from the first lateral edge by a first spacing dimension D1. The fourth well region has a fourth lateral edge separated from the second lateral edge by a second spacing dimension D2, which is different than D1.

Abstract: Methods and apparatus for ESD structures. A semiconductor device includes a first active area containing an ESD cell coupled to a first terminal and disposed in a well; a second active area in the semiconductor substrate, the second active area comprising a first diffusion of the first conductivity type for making a bulk contact to the well; and a third active area in the semiconductor substrate, separated from the first and second active areas by another isolation region, a portion of the third active area comprising an implant diffusion of the first conductivity type within a first diffusion of the second conductivity type and adjacent a boundary with the well of the first conductivity type; wherein the third active area comprises a diode coupled to the terminal and reverse biased with respect to the well of the first conductivity type.

Abstract: An electrostatic discharge (ESD) protection device includes a substrate; a source region of a first conductivity type in the substrate; a drain region of the first conductivity type in the substrate; a gate electrode overlying the substrate between the source region and the drain region; and a core pocket doping region of the second conductivity type within the drain region. The core pocket doping region does not overlap with an edge of the drain region.