In one example, an electrostatic discharge (ESD) protection circuit includes a first power supply having a first supply voltage, wherein the first power supply is connected to a first node. The ESD protection circuit also includes a second power supply having a second supply voltage, wherein the second power supply is connected to the first node. The ESD protection circuit also includes an inverter that receives an input voltage from the first node and produces an output voltage. An ESD discharge device receives the output voltage and provides a discharge path for the first power supply and the second power supply if the output voltage indicates occurrence of an ESD event affecting the first power supply or the second power supply.

A TFT substrate, an ESD protection circuit, and a method for manufacturing the TFT substrate. The TFT substrate comprises: a base substrate; a first gate provided on the base substrate; a first insulating layer provided on the first gate; a drain, a source, and an active layer provided on the first insulating layer; a second insulating layer provided on the drain, the source, and the active layer; and a second gate provided on the second insulating layer. In this way, display abnormality of a liquid crystal panel screen can be avoided.

We disclose a III-nitride semiconductor based heterojunction power device comprising: a first heterojunction transistor formed on a substrate, the first heterojunction transistor comprising: a first III-nitride semiconductor region formed over the substrate, wherein the first III-nitride semiconductor region comprises a first heterojunction comprising at least one two dimensional carrier gas; a first terminal operatively connected to the first III-nitride semiconductor region; a second terminal laterally spaced from the first terminal and operatively connected to the first III-nitride semiconductor region; a first plurality of highly doped semiconductor regions of a first polarity formed over the first III-nitride semiconductor region, the first plurality of highly doped semiconductor regions being formed between the first terminal and the second terminal; a first gate region operatively connected to the first plurality of highly doped semiconductor regions; and a second heterojunction transistor formed on the substrate. The second heterojunction transistor comprises: a second III-nitride semiconductor region formed over the substrate, wherein the second III-nitride semiconductor region comprises a second heterojunction comprising at least one two dimensional carrier gas; a third terminal operatively connected to the second III-nitride semiconductor region; a fourth terminal laterally spaced from the third terminal in the first dimension and operatively connected to the second III-nitride semiconductor region; a second gate region being formed over the second III-nitride semiconductor region, and between the third terminal and the fourth terminal. One of the first and second heterojunction transistors is an enhancement mode field effect transistor and the other of the first and second heterojunction transistors is a depletion mode field effect transistor.

A semiconductor device includes a floating buried doped region, a first doped region disposed between the floating buried doped region and a first major surface, and a semiconductor region disposed between the floating buried doped region and a second major surface. Trench isolation portions extend from the first major surface and terminate within the semiconductor region to define an active region. An insulated trench structure is laterally disposed between the trench isolation portions, terminates within the floating buried doped region, and defines a first portion and a second portion of the active region. A biasing semiconductor device is within the first portion, and a functional semiconductor device is within the second portion. The biasing semiconductor device is adapted to set a potential of the floating buried doped region and adapted to divert parasitic currents away from the functional semiconductor device.

A semiconductor device and a manufacturing method thereof are provided. The semiconductor device includes a substrate, a first well, a second well and doped regions. The substrate has heavily doped and lightly doped regions over the heavily doped region. The first wells are disposed in the lightly doped region and arranged as an array. The first wells have a conductive type opposite to a conductive type of the heavily doped and lightly doped regions. The second well is disposed in the substrate over the lightly doped region, and has an active region defined by an isolation structure. The first wells are overlapped with the second well. Top ends of the first wells are lower than a bottom end of the second well. The doped regions are separately located in the active region, and have a conductive type opposite to a conductive type of the second well.

A dual mode snap back circuit device is disclosed. The dual mode snap back device may be used for electrostatic discharge (ESD) protection, and may provide both positive ESD protection and negative ESD protection. The dual mode snap back device may implement both an n-type metal-oxide-semiconductor (NMOS) transistor (e.g., a gate-grounded NMOS transistor, such as a gate-grounded extended drain NMOS (GGEDNMOS) transistor) to provide protection against positive ESD events and a bipolar junction transistor (BJT) (e.g., a PNP BJT) to provide protection against negative ESD events. Other embodiments may be described and claimed.

A semiconductor device includes a first well, a first region and fourth regions of a first conductivity type as well as second regions, a third region, a second well of the second conductivity type. A first region is disposed in the first well and coupled to a first reference voltage terminal. Second regions are disposed in the first well, wherein one of the second regions is coupled to the first reference voltage terminal, and the second regions and the first well are included in a first transistor. A third region is disposed in the first well. A first resistive load is coupled between the third region and a second reference voltage terminal. A second well is coupled to the first well. Fourth regions are disposed in the second well, wherein the second well and at least one of the fourth regions are included in a second transistor.

Provided is a radiation-tolerant 3D unit MOSFET having at least one selected from a dummy drain (DD), an N-well layer (NW), a deep N-well layer (DNW), and a P+ layer to minimize an influence by a total ionization dose effect and an influence by a single event effect.

A high voltage device with self-electrostatic discharge protection. The device comprises: a semiconductor substrate; a first N-well (201), a P-well (202), and a second N-well (209) formed in the semiconductor substrate; a first N+ ion implantation region (203) and a first isolation region (207) formed in the first N-well (201); a second N+ ion implantation region (204) and a P+ ion implantation region (205) adjacent to the second N+ ion implantation region (204) that are formed in the P-well (202); a third N+ ion implantation region (208) formed in the second N-well (209); and a second isolation region (210) formed in the semiconductor substrate, the second isolation region (210) covering a portion of the second N-well (209) and a portion of the P-well (202), wherein the second N+ ion implantation region (203), the P+ ion implantation region (205), and the third N+ ion implantation region (208) constitute an NPN-type BJT, and the electrostatic discharge protection is achieved by means of the BJT.

A semiconductor device has an N-type substrate, a through conductor penetrating the N-type substrate, a protection target circuit provided on the N-type substrate, and an ESD protection circuit provided on the N-type substrate. The protection target circuit and the ESD protection circuit are connected together to the through conductor.