A method for fabricating a Polysilicon Thin-Film Transistor is provided. The method includes forming a polysilicon active layer, forming a first gate insulation layer and a first gate electrode sequentially on the active layer, conducting a first ion implantation process on the active layer by using the first gate electrode as a mask to form two doped regions at ends of the active layer, forming a second gate insulation layer and a second gate electrode sequentially on the first gate insulation layer and the first gate electrode, and conducting a second ion implantation process on the active layer by using the second gate electrode as another mask to form two source/drain implantation regions at two outer sides of the doped regions of the active layer. Accordingly, impurity concentration of the two doped regions is smaller than that of the two source/drain implantation regions.

A semiconductor device including a first line configured to receive a power supply voltage, a second line configured to be coupled to a load of the semiconductor device, first and second metal-oxide-semiconductor (MOS) transistors coupled in series between the first line and the second line, each of the first and second MOS transistors having a drain electrode and a gate electrode, the drain electrode of the first MOS transistor being coupled to the drain electrode of the second MOS transistor, a third line coupled to the gate electrode of the first MOS transistor, and a fourth line coupled to the gate electrode of the second MOS transistor, the third and fourth lines being electrically separated from each other.

A semiconductor device includes a first cell. The first cell includes a first functional feature, a first sensitivity region, at least one anchor node, wherein each of the at least one anchor node is different from the first functional feature, and a number of anchor nodes of the at least one anchor node linked to the first functional feature is based on a position of the first functional feature relative to the first sensitivity region. The semiconductor device further includes a second cell abutting the first cell. The second cell includes a second functional feature, wherein the second functional feature satisfies a minimum spacing requirement with respect to the first functional feature.

An integrated circuit (IC) comprises a first conductor in one layer of the IC, a second conductor in another layer of the IC, and a first metal plug connecting the first and second conductors. The IC further comprises an atomic source conductor (ASC) in the one layer of the IC and joined to the first conductor, and a second metal plug connecting the ASC to a voltage source of the IC. The first conductor and the ASC are configured to be biased to different voltages so as to establish an electron path from the second metal plug to the first metal plug such that the ASC acts as an active atomic source for the first conductor.

A power integrated module, including at least one first bridge formed in a chip, wherein the first bridge includes: a first upper bridge switch, formed by a plurality of first sub switches formed in the chip connected in parallel, and including a first, a second and a control end; a first lower bridge switch, formed by a plurality of second sub switches formed in the chip connected in parallel, and including a first, a second and a control end; a first electrode, connected to the first end of the first upper bridge switch; a second electrode, connected to the second end of the first lower bridge switch; and a third electrode, connected to the second end of the first upper bridge switch and the first end of the first lower bridge switch, wherein the first, the second and the third electrode are bar-type electrodes arranged side by side.

The present disclosure provides an array substrate and a display device that can suppress the adverse effects in display due to difference in gray-scale luminance of adjacent two rows caused by variation in capacitance of adjacent two rows of TFTs as the result of displacement of the data lines. Scan lines and data lines crossing each other are arranged on the array substrate. Each row of the scan lines is provided with a gate driver circuit, wherein each row of the scan lines is further provided with a compensation capacitor connected to the gate driver circuit, the compensation capacitor including a first metal layer and a second metal layer that are overlapped with each other to form an overlap region at which the first metal layer is isolated from the second metal layer by an insulation layer, wherein the compensation capacitor in an N.sup.th row has a capacitance that changes in a direction opposite to the direction in which the capacitance of the compensation capacitor in an N+1.sup.th row changes, and the compensation capacitor in the N.sup.th row has a capacitance that changes in the same direction as the direction in which the capacitance of a thin film transistor capacitor in the N+1.sup.th row changes, where N is a natural number greater than or equal to 1.

An igniter is not provided with a depression IGBT and is configured such that a distance between a main IGBT and a sense IGBT is equal to or greater than 100 m and equal to or less than 700 m and preferably equal to or greater than 100 m and equal to or less than 200 m. The igniter is controlled such that, before the overcurrent of the main IGBT reaches a predetermined upper limit, a sense current of the sense IGBT is saturated. Therefore, it is possible to provide the igniter which has a small size and prevents the overshoot of a collector current of the main IGBT when a current is limited and an internal combustion engine ignition apparatus which includes the igniter, has a small size, and prevents an ignition error.

Light emitting devices and methods of integrating micro LED devices into light emitting device are described. In an embodiment a light emitting device includes a reflective bank structure within a bank layer, and a conductive line atop the bank layer and elevated above the reflective bank structure. A micro LED device is within the reflective bank structure and a passivation layer is over the bank layer and laterally around the micro LED device within the reflective bank structure. A portion of the micro LED device and a conductive line atop the bank layer protrude above a top surface of the passivation layer.

A robust electrostatic (ESD) protection device is provided. In one example, the ESD protection device is configured to accommodate three nodes. When used with a differential signal device, the first and second nodes may be coupled with the differential signal device's BP and BM signal lines, respectively, and the third node may be coupled to a voltage source. This allows for a single ESD protection device to be used to protect the signal lines of the differential signal device, thus providing significant substrate area savings as compared to the conventional means of using three dual-node ESD protection devices to accomplish substantially the same protection mechanism. Moreover, the ESD protection device may be structurally designed to handle high voltage ESD events, as required by the FlexRay standard.

A stitched device is disclosed. The stitched device includes first and second base devices having first and second stitched interconnects electrically coupled in a stitching level. This enables a single substrate of the stitched device to have electrically coupled first and second base devices.