A semiconductor device includes a first electrode, a first semiconductor layer of a first dopant type on the first electrode. A first region of the semiconductor device includes a second semiconductor layer of the second dopant type on the first semiconductor layer, a third semiconductor layer of the first dopant type on the second semiconductor layer, and a second electrode extending though the second and third semiconductor layers and inwardly of the first semiconductor layer. A second region of the semiconductor device includes an insulating layer over the first semiconductor layer, a fourth semiconductor layer of the first or second dopant type on the insulating layer, a fifth semiconductor layer of a different dopant type on the insulating layer and surrounding the fourth semiconductor layer, and a sixth semiconductor layer of the same dopant type on the insulation layer and surrounding the fifth semiconductor layer.

The present disclosure provides a memory cell that includes a resistive memory element disposed between a first conductor and a second conductor, the first conductor and the second conductor configured to activate the resistive memory element. The memory cell also includes a diode disposed in parallel with the memory element between the first conductor and the second conductor.

An electrical circuit, in some embodiments, comprises a control circuit having a plurality of switches and an electrical load having a plurality of load components. A first of the plurality of switches is configured to control a first of the plurality of load components. A second of the plurality of switches is configured to control a second of the plurality of load components synchronously with the first of the plurality of switches.

A semiconductor device including a semiconductor switch circuit and a drive circuit. The semiconductor switch circuit includes a semiconductor switch and a temperature sensor for detecting a temperature in a periphery of the semiconductor switch. The drive circuit includes an overheating protection unit configured to, upon determining that the detected temperature of the semiconductor switch reaches an overheating protection temperature, perform overheating protection of the semiconductor switch and issue an overheating protection alarm signal. The drive circuit also includes an advance warning control unit configured to set a threshold temperature that is lower than the overheating protection temperature, and upon determining that the detected temperature reaches the threshold temperature, to output an advance warning signal before the overheating protection becomes operational. The overheating protection alarm signal and the advance warning signal are outputted from a same terminal of the drive circuit and are of different signal levels.

A device includes a vertical semiconductor switch including (i) a gate terminal and a first terminal provided on a substrate and (ii) a second terminal provided on the substrate, where the vertical semiconductor switch is configured to electrically connect or disconnect the first terminal and the second terminal, a first insulative film provided on the substrate, a second insulative film provided on the substrate, where the second insulative film is in contact with the first insulative film and thinner than the first insulative film, and a zener diode formed on the first insulative film and the second insulative film, where the zener diode includes a first portion that is formed on the first insulative film and connected to the first surface of the substrate and a second portion that is formed on the second insulative film and connected to the gate terminal.

A diffusion diode including a p.sup.+ diffusion region, a p-type diffusion region, and an n.sup.+ diffusion region is formed in the front surface of a semiconductor substrate. A polysilicon diode including a p.sup.+ layer and an n.sup.+ layer is formed on top of a local insulating film formed on the front surface of the semiconductor substrate and faces the diffusion diode in the depth direction. The diffusion diode and the polysilicon diode are reverse-connected by electrically connecting the n.sup.+ diffusion region to the n.sup.+ layer, thereby forming a lateral protection device. The p.sup.+ layer and p.sup.+ diffusion region are respectively electrically connected to a high voltage first terminal and a low voltage second terminal of the lateral protection device. The polysilicon diode blocks a forward current generated in the diffusion diode when the electric potential of the first terminal becomes lower than the electric potential of the second terminal.

The betas of the bipolar transistors in a BiCMOS semiconductor structure are increased by forming the emitters of the bipolar transistors with two implants: a source-drain implant that forms a first emitter region at the same time that the source and drain regions are formed, and an additional implant that forms a second emitter region at the same time that another region is formed. The additional implant has an implant energy that is greater than the implant energy of the source-drain implant.

A semiconductor device includes a first nitride semiconductor layer having a first region, a second nitride semiconductor layer that is on the first nitride semiconductor layer and contains carbon and silicon, a third nitride semiconductor layer that is on the second nitride semiconductor layer and has a second region, a fourth nitride semiconductor layer on the third nitride semiconductor layer, the fourth nitride semiconductor layer having a band gap that is wider than a band gap of the third nitride semiconductor layer, a source electrode that is on the fourth nitride semiconductor layer and is electrically connected to the first region, a drain electrode that is on the fourth nitride semiconductor layer and is electrically connected to the second region, and a gate electrode that is on the fourth nitride semiconductor layer and is between the source electrode and the drain electrode.

The invention provides a semiconductor device layout structure disposed in an active region. The semiconductor device layout structure includes a first well region having a first conduction type. A second well region having a second conduction type opposite the first conduction type is disposed adjacent to and enclosing the first well region. A first doped region having the second conduction type is disposed within the first well region. A second doped region having the second conduction type is disposed within the first well region. The second doped region is separated from and surrounds the first doped region. A third doped region having the second conduction type is disposed within the second well region.

A display apparatus includes a timing controller configured to output a gate control signal through gate control lines, a gate driver configured to output gate signals in response to the gate control signal provided from the gate control lines, pixels configured to receive data voltages in response to the gate signals, and first and second static electricity prevention parts connected to the gate control lines in parallel configured to discharge a static electricity. Each of the first and second static electricity prevention parts is configured to form current paths, which are smaller in number than a number of the gate control lines, to discharge the static electricity and the static electricity configured to be discharged by the first static electricity prevention part has a polarity different from a polarity of the static electricity configured to be discharged by the second static electricity prevention part.