An integrated circuit device including a semiconductor substrate, a first bonding pad structure, a second bonding pad structure, and an internal bonding wire is provided. The first bonding pad structure is disposed on a surface of the semiconductor substrate and exposed outside of the semiconductor substrate. The second bonding pad structure is disposed on the surface of the semiconductor substrate and exposed outside of the semiconductor substrate. The first bonding pad structure is electrically coupled to the second bonding pad structure via the internal bonding wire. The integrated circuit device having a better electrical performance is provided by eliminating internal resistance drop in power supply trails or ground trails, and improving signal integrity of the integrated circuit device.

A display panel is provided. The display panel has an active area and a border area out of the active area. The display panel includes a plurality of pixels, a first gate driver portion, a plurality of scan lines and a multiplexer portion. The pixels are located in the active area. The first gate driver portion is located in the border area. The scan lines are located in the active area, and connected to the first gate driver portion. The multiplexer portion is located in the border area. The multiplexer portion and the first gate driver portion at least partially overlap along a direction parallel to one of the plurality of scan lines.

Three-dimensional electrostatic discharge (ESD) semiconductor devices are fabricated together with three-dimensional non-ESD semiconductor devices. For example, an ESD diode and FinFET are fabricated on the same bulk semiconductor substrate. A spacer merger technique is used in the ESD portion of a substrate to create double-width fins on which the ESD devices can be made larger to handle more current.

A cascode transistor circuit having an active region, the active region having a source, a drain, a floating source/drain, a first gate disposed between the source and the floating source/drain and a second gate disposed between the floating source/drain and the drain. A first gate pad is displaced from the active region and is electrically connected to the first gate and a second gate pad is displaced from the active region and is electrically connected to the second gate. The first and the second gate pads are disposed on opposite sides of the active region.

A semiconductor device includes high-voltage (HV) and low-voltage (LV) MOS's formed in a substrate. The HV MOS includes a first semiconductor region having a first-type conductivity and a first doping level, a second semiconductor region having the first-type conductivity and a second doping level lower than the first doping level, a third semiconductor region having a second-type conductivity, and a fourth semiconductor region having the first-type conductivity. The first, second, third, and fourth semiconductor regions are arranged along a first direction, and are drain, drift, channel, and source regions, respectively, of the HV MOS. The LV MOS includes the fourth semiconductor region, a fifth semiconductor region having the second-type conductivity, and a sixth semiconductor region having the first-type conductivity. The fourth, fifth, and sixth semiconductor regions are arranged along a second direction different from the first direction, and are drain, channel, and source regions, respectively, of the LV MOS.

A transparent display device is provided. The transparent display device includes a transparent display panel and a layer being disposed on any display surface of the transparent display panel and having both of the transmission function and the reflection function. The layer covers the display surface of the entire transparent display panel.

An ESD protection device including a Si substrate with an ESD protection circuit formed at the surface of the substrate; pads formed on the Si substrate; a rewiring layer opposed to the surface of the Si substrate, which includes terminal electrodes electrically connected to the pads. The rewiring layer includes a SiN protection film formed on the surface of the Si substrate to cover parts of the pads except regions in contact with openings (contact holes) formed in a resin layer, and the resin layer that is lower in dielectric constant than the SiN protection film, and formed between the SiN protection film and the terminal electrodes. Thus, provided is a semiconductor device which can reduce the generation of parasitic capacitance, and eliminates variation in parasitic capacitance generated.

An integrated circuit includes a semiconductor body with a first semiconductor layer, an insulation layer on the first semiconductor layer, and a second semiconductor layer on the insulation layer. The integrated circuit further includes a plurality of transistors each including a load path and a control node The load paths are connected in series, and the plurality of transistors are at least partially integrated in the second semiconductor layer. A voltage limiting structure is connected in parallel with the load path of one of the plurality of transistors, wherein the voltage limiting structure is integrated in the first semiconductor layer and is connected to the one of the plurality of transistors through two electrically conducting vias extending through the insulation layer.

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 described techniques address issues associated with electrostatic discharge (ESD) protection for multi-die integrated circuits (ICs). The techniques include the use of two or more semiconductor dies within a multi-die IC, which may include a first semiconductor die without ESD protection but with full ESD exposure. The first semiconductor receives ESD protection via a second semiconductor die that is integrated as part of the same package with the first semiconductor die. The second semiconductor die may be electrically more remote from ESD-exposed pins compared to the first semiconductor die. The first semiconductor die may include integrated passive devices. The second semiconductor die enables ESD protection for both semiconductor dies in the same integrated IC package.