Abstract: A bidirectional electrostatic discharge protection device includes a first transient voltage suppressor chip, a second transient voltage suppressor chip, a first conductive wire, and a second conductive wire. The first transient voltage suppressor chip includes a first diode and a first bipolar junction transistor. The first diode and the first bipolar junction transistor are electrically connected to a first pin. The second transient voltage suppressor chip includes a second diode and a second bipolar junction transistor. The second diode and the second bipolar junction transistor are electrically connected to a second pin. The first conductive wire is electrically connected between the first diode and the second bipolar junction transistor. The second conductive wire is electrically connected between the second diode and the first bipolar junction transistor.

Abstract: A transient voltage suppression device includes a P-type semiconductor layer, a first N-type well, a first N-type heavily-doped area, a first P-type heavily-doped area, a second P-type heavily-doped area, and a second N-type heavily-doped area. The first N-type well and the second N-type heavily-doped area are formed in the layer. The first P-type heavily-doped area is formed in the first N-type well. The first P-type heavily-doped area is spaced from the bottom of the first N-type well. The second P-type heavily-doped area is formed within the first N-type well and spaced from the sidewall of the first N-type well. The second P-type heavily-doped area is formed between the first P-type heavily-doped area and the second N-type heavily-doped area.

Abstract: A multi-channel transient voltage suppression device includes a semiconductor substrate, a semiconductor layer, at least two bidirectional transient voltage suppression structures, and at least one isolation trench. The semiconductor substrate, having a first conductivity type, is coupled to a grounding terminal. The semiconductor layer, having a second conductivity type opposite to the first conductivity type, is formed on the semiconductor substrate. The bidirectional transient voltage suppression structures are formed in the semiconductor layer. Each bidirectional transient voltage suppression structure is coupled to an input/output (I/O) pin and the grounding terminal. The isolation trench is formed in the semiconductor substrate and the semiconductor layer and formed between the bidirectional transient voltage suppression structures. The isolation trench has a height larger than the height of the semiconductor layer and surrounds the bidirectional transient voltage suppression structures.

Abstract: A transient voltage suppression device includes a P-type semiconductor layer, a first N-type well, a first N-type heavily-doped area, a first P-type heavily-doped area, a second P-type heavily-doped area, and a second N-type heavily-doped area. The first N-type well and the second N-type heavily-doped area are formed in the layer. The first P-type heavily-doped area is formed in the first N-type well. The first P-type heavily-doped area is spaced from the bottom of the first N-type well. The second P-type heavily-doped area is formed within the first N-type well and spaced from the sidewall of the first N-type well. The second P-type heavily-doped area is formed between the first P-type heavily-doped area and the second N-type heavily-doped area.

Abstract: An embedded NMOS triggered silicon controlled rectification device includes a P-type substrate, at least one rectifying zone, and at least one trigger. The rectifying zone includes a first N-type heavily doped area, an N-type well, and a first P-type heavily doped area. Alternatively, the device includes an N-type substrate, a first P-type well, at least one rectifying zone, and at least one trigger. The rectifying zone includes a second P-type well, a first N-type heavily doped area, and a first P-type heavily doped area. The trigger cooperates with the P-type substrate or the first P-type well to form at least one NMOSFET. The trigger is independent to the rectifying zone. The first P-type heavily doped area is arranged between the trigger and the first N-type heavily doped area.

Abstract: An embedded NMOS triggered silicon controlled rectification device includes a P-type substrate, at least one rectifying zone, and at least one trigger. The rectifying zone includes a first N-type heavily doped area, an N-type well, and a first P-type heavily doped area. Alternatively, the device includes an N-type substrate, a first P-type well, at least one rectifying zone, and at least one trigger. The rectifying zone includes a second P-type well, a first N-type heavily doped area, and a first P-type heavily doped area. The trigger cooperates with the P-type substrate or the first P-type well to form at least one NMOSFET. The trigger is independent to the rectifying zone. The first P-type heavily doped area is arranged between the trigger and the first N-type heavily doped area.

Abstract: A semiconductor package includes an interconnect substrate, an insulating adhesive, a transient voltage suppressor (TVS) chip, at least one first conductive wire, and at least one second conductive wire. The interconnect substrate includes a bottom layer and a top layer, the bottom layer includes two first conductive blocks and a first insulating block therebetween, the top layer includes two second conductive blocks and a second insulating block therebetween, the second conductive blocks are respectively formed on the first conductive blocks, and the second insulating block is formed on the first insulating block. The insulating adhesive is formed on the second insulating block. The TVS chip is formed on the insulating adhesive without overlapping the second conductive blocks. The first conductive wire and the second conductive wire are respectively electrically connected to the second conductive blocks and electrically connected to the TVS chip.

Abstract: A transient voltage suppression device includes a lightly-doped semiconductor structure, a first doped well, a first heavily-doped area, a first buried area, and a second heavily-doped area. The lightly-doped semiconductor structure has a first conductivity type. The first doped well has a second conductivity type and is formed in the lightly-doped semiconductor structure. The first heavily-doped area has the second conductivity type and is formed in the first doped well. The first buried area has the first conductivity type and is formed in the lightly-doped semiconductor structure and under the first doped well, and the first buried area is adjacent to the first doped well. The second heavily-doped area has the second conductivity type and is formed in the lightly-doped semiconductor structure.

Abstract: A transient voltage suppression device includes a lightly-doped semiconductor structure, a first doped well, a first heavily-doped area, a first buried area, and a second heavily-doped area. The lightly-doped semiconductor structure has a first conductivity type. The first doped well has a second conductivity type and is formed in the lightly-doped semiconductor structure. The first heavily-doped area has the second conductivity type and is formed in the first doped well. The first buried area has the first conductivity type and is formed in the lightly-doped semiconductor structure and under the first doped well, and the first buried area is adjacent to the first doped well. The second heavily-doped area has the second conductivity type and is formed in the lightly-doped semiconductor structure.

Abstract: An improved transient voltage suppression device includes a semiconductor substrate, a transient voltage suppressor, at least one first diode, at least one conductive pad, and at least one second diode. The transient voltage suppressor has an N-type heavily-doped clamping area. The first anode of the first diode is electrically connected to the N-type heavily-doped clamping area. The conductive pad is electrically connected to the first cathode of the first diode. The second anode of the second diode is electrically connected to the conductive pad and the second cathode of the second diode is electrically connected to the transient voltage suppressor. The first anode is closer to the N-type heavily-doped clamping area rather than the conductive pad. The conductive pad is closer to the N-type heavily-doped clamping area rather than the second anode.

Abstract: A vertical transient voltage suppressor for protecting an electronic device is disclosed. The vertical transient voltage includes a conductivity type substrate having highly doping concentration; a first type lightly doped region is arranged on the conductivity type substrate, wherein the conductivity type substrate and the first type lightly doped region respectively belong to opposite types; a first type heavily doped region and a second type heavily doped region are arranged in the first type lightly doped region, wherein the first and second type heavily doped regions and the conductivity type substrate belong to same types; and a deep first type heavily doped region is arranged on the conductivity type substrate and neighbors the first type lightly doped region, wherein the deep first type heavily doped region and the first type lightly doped region respectively belong to opposite types, and wherein the deep first type heavily doped region is coupled to the first type heavily doped region.

Abstract: An electrostatic discharge protection device structure is disclosed, which comprises a semiconductor substrate and an N-type epitaxial layer arranged on the semiconductor substrate. At least one snapback cascade structure is arranged in the N-type epitaxial layer, wherein the snapback cascade structure further comprises first and second P-type wells arranged in the N-type epitaxial layer. First and second heavily doped areas arranged in the first P-type well respectively belong to opposite types. And, third and fourth heavily doped areas arranged in the second P-type well respectively belong to opposite types, wherein the second and third heavily doped areas respectively belong to opposite types and are electrically connected with each other. When the first heavily doped area receives an ESD signal, an ESD current flows from the first heavily doped area to the fourth heavily doped area through the first P-type well, the N-type epitaxial layer, and the second P-type well.

Abstract: A new ESD protection device with an integrated-circuit vertical transistor structure is disclosed, which includes a heavily doped p-type substrate (P+ substrate), a n-type well (N well) in the P+ substrate, a heavily doped p-type diffusion (P+ diffusion) in the N well, a heavily doped n-type diffusion (N+ diffusion) in the N well, and a p-type well (P well) surrounding the N well in the P+ substrate. A bond pad is connected to both the P+ and N+ diffusions, and a ground is coupled to the P+ substrate. Another P+ diffusion is implanted in the N well or another N+ diffusion is implanted in the P well to form a Zener diode, which behaves as a trigger for the PNP transistor when a positive ESD zaps. A parasitic diode is formed at the junction between the P+ substrate and the N well, to bypass a negative ESD stress on the bond pad.

Abstract: A vertical transient voltage suppressor for protecting an electronic device is disclosed. The vertical transient voltage includes a conductivity type substrate having highly doping concentration; a first type lightly doped region is arranged on the conductivity type substrate, wherein the conductivity type substrate and the first type lightly doped region respectively belong to opposite types; a first type heavily doped region and a second type heavily doped region are arranged in the first type lightly doped region, wherein the first and second type heavily doped regions and the conductivity type substrate belong to same types; and a deep first type heavily doped region is arranged on the conductivity type substrate and neighbors the first type lightly doped region, wherein the deep first type heavily doped region and the first type lightly doped region respectively belong to opposite types, and wherein the deep first type heavily doped region is coupled to the first type heavily doped region.

Abstract: A new ESD protection device with an integrated-circuit vertical transistor structure is disclosed, which includes a heavily doped p-type substrate (P+ substrate), a n-type well (N well) in the P+ substrate, a heavily doped p-type diffusion (P+ diffusion) in the N well, a heavily doped n-type diffusion (N+ diffusion) in the N well, and a p-type well (P well) surrounding the N well in the P+ substrate. A bond pad is connected to both the P+ and N+ diffusions, and a ground is coupled to the P+ substrate. Another P+ diffusion is implanted in the N well or another N+ diffusion is implanted in the P well to form a Zener diode, which behaves as a trigger for the PNP transistor when a positive ESD zaps. A parasitic diode is formed at the junction between the P+ substrate and the N well, to bypass a negative ESD stress on the bond pad.

Abstract: A diode with low substrate current leakage and suitable for BiCMOS process technology. A buried layer is formed on a semiconductor substrate. A connection region and well contact the buried layer. Isolation regions are adjacent to two sides of the buried layer, each deeper than the buried layer. The isolation regions and the buried layer isolate the connection zone and the well from the substrate. The first doped region in the well is a first electrode. The well and the connection region are electrically connected, acting as a second electrode.

Abstract: Diode strings and electrostatic discharge circuits characterized by low current leakage. Each diode region provides a diode and has first and second regions. The first region is of a first conductive type and formed on a substrate, acting as a first electrode of a diode. The second region is of a second conductive type opposite to the first conductive type, formed in the first region and acting as a second electrode of a corresponding diode. The diodes are forward connected in series to form major anode and cathode of the diode string. An isolation region is of the second conductive type to isolate those diode regions. A bias resistor is connected between the isolation region and a first power line. During normal operation, the voltage of the first power line is not within the range between the voltages of the major anode and cathode.

Abstract: An ESD protection circuit that protects a mixed-voltage input/output (I/O) buffer circuit in an integrated circuit is provided. The ESD protection circuit includes an ESD discharging circuit coupled to the I/O pad and ESD detection circuit coupled to the discharging circuit providing a means for detecting an ESD and triggering the discharging circuit to conduct the ESD to ground. The ESD discharging circuit comprises stacked NMOS transistors or a field oxide device (FOD). The protection circuit can also be used in an ESD protection circuit for a high-voltage-tolerant input pad or to protect multiple input pads and/or multiple I/O pads in an integrated circuit.

Abstract: A diode with low substrate current leakage and suitable for BiCMOS process technology. A buried layer is formed on a semiconductor substrate. A connection region and well contact the buried layer. Isolation regions are adjacent to two sides of the buried layer, each deeper than the buried layer. The isolation regions and the buried layer isolate the connection zone and the well from the substrate. The first doped region in the well is a first electrode. The well and the connection region are electrically connected, acting as a second electrode.

Abstract: A diode with low substrate current leakage and suitable for BiCMOS process technology. A buried layer is formed on a semiconductor substrate. A connection region and well contact the buried layer. Isolation regions are adjacent to two sides of the buried layer, each deeper than the buried layer. The isolation regions and the buried layer isolate the connection zone and the well from the substrate. The first doped region in the well is a first electrode. The well and the connection region are electrically connected, acting as a second electrode.