Abstract: A circuit device includes core circuitry. The circuit device further includes a first set of guard rings having a first dopant type, the first set of guard rings being around a periphery of the core circuitry, the first set of guard rings comprising a first guard ring and a second guard ring. The circuit device further includes a second set of guard rings having a second dopant type, the second dopant type being opposite to the first dopant type, wherein at least one guard ring of the second set of guard rings is around a periphery of at least one guard ring of the first set of guard rings, and the second set of guard rings comprises a third guard ring and a fourth guard ring.

Abstract: The present disclosure provides a three dimensional integrated circuit having a plurality of dies. Each die includes a trigger line common to the other dies, and an ESD detection circuit coupled to the common trigger line and to a first power line common to the other dies, wherein when the ESD detection circuit of one of the plural dies detects an ESD event, the ESD detection circuit is configured to generate a control signal to the common trigger line to control a power clamp in each of the plural dies to clamp an ESD event to the common first power line or a second power line.

Abstract: A circuit includes a driver circuit between a first and second power supply nodes, and a first and second electrostatic discharge (ESD) protection circuits. The driver circuit is configured to generate a pair of differential signals at a first output node and a second output node. The first ESD protection circuit is coupled between the first output node and the second power supply node. The first ESD protection circuit includes a first transistor, and the first transistor includes a drain region and a source region in a well region. The second ESD protection circuit is coupled between the second output node and the second power supply node. The second ESD protection circuit includes a second transistor, and the second transistor includes a drain region and a source region in the well region.

Abstract: A semiconductor device is disclosed that includes a first well of a first conductivity type, a second well of a second conductivity type, a plurality of first regions, a second region and a plurality of electrodes. The first regions are of the first conductivity type and are formed in the second well. The second region is of the second conductivity type and is formed in the first well. Each of the electrodes is formed upon the second well and between adjacent two first regions of the first regions.

Abstract: A device includes a plurality of STI regions, a plurality of semiconductor strips between the STI regions and parallel to each other, and a plurality of semiconductor fins over the semiconductor strips. A gate stack is disposed over and crossing the plurality of semiconductor fins. A drain epitaxy semiconductor region is disposed on a side of the gate stack and connected to the plurality of semiconductor fins. The drain epitaxy semiconductor region includes a first portion adjoining the semiconductor fins, wherein the first portion forms a continuous region over and aligned to the plurality of semiconductor strips. The drain epitaxy semiconductor region further includes second portions farther away from the gate stack than the first portion. Each of the second portions is over and aligned to one of the semiconductor strips. The second portions are parallel to each other, and are separated from each other by a dielectric material.

Abstract: A method comprises forming an active region including a first fin and a second fin over a substrate, wherein the first fin and the second fin are separated by an isolation region, depositing an epitaxial growth block layer over the active region, patterning the epitaxial growth block layer to define a first growth area and a second growth area and growing an N+ region in the first growth area and a P+ region in the second growth area.

Abstract: The present disclosure provides a three dimensional integrated circuit having a plurality of dies. Each die includes a trigger line common to the other dies, the trigger line controlling the power of a power clamp in each respective die, a dedicated electrostatic discharge (ESD) line for each respective die, and an ESD detection circuit connected to the dedicated ESD line and to a first power line common to the other dies. When an input signal is received by the ESD detection circuit of one of the plural dies, the ESD detection circuit generates an output signal to the common trigger line to supply power to the power clamp in each of the plural dies to clamp ESD voltage or current to the common first power line or a second power line.

Abstract: A structure comprises an N+ region formed over a first fin of a substrate, a P+ region formed over a second fin of the substrate, wherein the P+ region and the N+ region form a diode, a shallow trench isolation region formed between the P+ region and the N+ region and a first epitaxial growth block region formed over the shallow trench isolation region and between the N+ region and the P+ region, wherein a forward bias current of the diode flows through a path underneath the shallow trench isolation region.

Abstract: A semiconductor device may include body contacts on a finFET device for ESD protection. The semiconductor device comprises a semiconductor fin, a source/drain region and a body contact. The source/drain region and the body contact are in the semiconductor fin. A portion of the fin is laterally between the source/drain region and the body contact. The semiconductor fin is on a substrate.

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: A semiconductor device includes semiconductor fins on semiconductor strips on a substrate. The semiconductor fins are parallel to each other. A gate stack is over the semiconductor fins, and a drain epitaxy semiconductor region is disposed laterally from a side of the gate stack and on the semiconductor strips. A first dielectric layer is over the substrate, and the first dielectric layer has a first metal layer. A second dielectric layer is over the first dielectric layer, and the second dielectric layer has a second metal layer. Vias extend from the second metal layer and through the first dielectric layer, and the vias are electrically coupled to the drain epitaxy semiconductor region.

Abstract: A semiconductor device is disclosed that includes a first well of a first conductivity type, a second well of a second conductivity type, a plurality of first regions, a second region and a plurality of electrodes. The first regions are of the first conductivity type and are formed in the second well. The second region is of the second conductivity type and is formed in the first well. Each of the electrodes is formed upon the second well and between adjacent two first regions of the first regions.

Abstract: A semiconductor device may include body contacts on a finFET device for ESD protection. The semiconductor device comprises a semiconductor fin, a source/drain region and a body contact. The source/drain region and the body contact are in the semiconductor fin. A portion of the fin is laterally between the source/drain region and the body contact. The semiconductor fin is on a substrate.

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 ESD protection circuit for an RF circuit includes first and second power supply voltage terminals for first and second power supply voltages and a power clamp coupled between the terminals. An RF input pad is configured to receive an input signal having an RF operating frequency. A resonance circuit is coupled to the RF input pad. A first ESD current path from the RF input pad to the first power supply voltage terminal includes the resonance circuit and a first ESD block configured to direct an ESD pulse of a first polarity toward the first terminal. A second ESD current path from the RF input pad to the second power supply voltage terminal includes the resonance circuit and a second ESD block configured to direct an ESD pulse of a second polarity toward the second terminal.

Abstract: A device includes a plurality of STI regions, a plurality of semiconductor strips between the STI regions and parallel to each other, and a plurality of semiconductor fins over the semiconductor strips. A gate stack is disposed over and crossing the plurality of semiconductor fins. A drain epitaxy semiconductor region is disposed on a side of the gate stack and connected to the plurality of semiconductor fins. The drain epitaxy semiconductor region includes a first portion adjoining the semiconductor fins, wherein the first portion forms a continuous region over and aligned to the plurality of semiconductor strips. The drain epitaxy semiconductor region further includes second portions farther away from the gate stack than the first portion. Each of the second portions is over and aligned to one of the semiconductor strips. The second portions are parallel to each other, and are separated from each other by a dielectric material.

Abstract: An apparatus includes an interposer and a plurality of dies stacked on the interposer. The interposer includes a first conductive network of a first trigger bus. Each of the plurality of dies includes a second conductive network of a second trigger bus, and an ESD detection circuit and an ESD power clamp electrically connected between a first power line and a second power line, and electrically connected to the second conductive network of the second trigger bus. The second conductive network of the second trigger bus in each of the plurality of dies is electrically connected to the first conductive network of the first trigger bus. Upon receiving an input signal, the ESD detection circuit is configured to generate an output signal to the corresponding second conductive network of the second trigger bus to control the ESD power clamps in each of the plurality of dies.

Abstract: An integrated circuit device includes at least two epitaxially grown active regions grown onto a substrate, the active regions being placed between two gate devices. The device further includes at least one dummy gate between two epitaxially grown active regions. Each active region is substantially uniform in length.

Abstract: A latch-up prevention structure and method for ultra-small high voltage tolerant cell is provided. In one embodiment, the integrated circuit includes an input and/or output pad, a floating high-voltage n-well (HVNW) connected to the input and/or output pad through a P+ in the floating HVNW and also connected to a first voltage supply, a low-voltage n-well (LVNW) connected to a second voltage supply through a N+ in the LVNW, a HVNW control circuit, and a guard-ring HVNW, where the first voltage supply has higher voltage level than the second voltage supply, guard-ring HVNW is inserted in between the floating HVNW and LVNW to prevent a latch-up path between a P+ in HVNW and N+ in LVNW by using the HVNW control circuit that controls the guard-ring HVNW's voltage level. The guard-ring HVNW's voltage level is matched by the floating HVNW's voltage level.

Abstract: An electrostatic discharge (ESD) protection device includes a well region formed from semiconductor material with a first doping type and a floating base formed from semiconductor material with a second doping type. The floating base is disposed vertically above the well region. The ESD also includes a first terminal receiving region formed from semiconductor material with a third doping type. The first terminal receiving region is disposed vertically above the floating base. The ESD further includes a second terminal receiving region. The second terminal receiving region is laterally spaced apart from the first terminal receiving region by silicon trench isolation (STI) region. In some embodiments, the second terminal receiving region is formed from semiconductor material with the third doping type to form a bipolar junction transmitter (BJT) or with a fourth doping type to form a silicon controlled rectifier (SCR).