125results about How to "Minimizes parasitic capacitance" patented technology

An organic light emitting diode (OLED) display includes at least one shield electrode between a cathode layer and an OLED drive circuit. The OLED drive circuit has at least one thin-film transistor (TFT), and the shield electrode is disposed to correspond to the thin-film transistor and closer to the cathode layer, covering an entire region between the source and drain of the thin-film transistor. The shield electrode is either grounded or tied to the gate of the thin-film transistor, to thereby minimize parasitic capacitances in the pixels of the display to enhance the display performance. The presented architecture enables high density drive circuit integration in amorphous silicon or other technologies, yet preserving a high display aperture ratio.

A pixel current driver comprises a plurality of thin film transistors (TFTs) each having dual gates and for driving OLED layers. A top gate of the dual gates is formed between a source and a drain of each of the thin film transistors, to thereby minimize parasitic capacitance. The top gate is grounded or electrically tied to a bottom gate. The plurality of thin film transistors may be two thin film transistors formed in voltage-programmed manner or five thin film transistors formed in a current-programmed ΔV_T-compensated manner. Other versions of the current-programmed circuit with different numbers of thin film transistors are also presented that compensate for δV_T. The OLED layer are continuous and vertically stacked on the plurality of thin film transistors to provide an aperture ratio close to 100%.

A through-wafer interconnect and a method for fabricating the same are disclosed. The method starts with a conductive wafer to form a patterned trench by removing material of the conductive wafer. The patterned trench extends in depth from the front side to the backside of the wafer, and has an annular opening generally dividing the conductive wafer into an inner portion and an outer portion whereby the inner portion of the conductive wafer is insulated from the outer portion and serves as a through-wafer conductor. A dielectric material is formed or added into the patterned trench mechanical to support and electrically insulate the through-wafer conductor. Multiple conductors can be formed in an array.

Methods for forming semiconductor memory structures including air gaps between adjacent gate structures are provided. The volume of the air gaps is maximized and the width thereof made uniform in order to minimize the parasitic capacitance and any variance therein between the gate structures. The methods include forming an insulation layer between adjacent gate structures and subsequently etching the insulation layer to leave an air gap. Devices fabricated in accordance with the methods are also provided.

Provided is a touch panel-integrated organic light emitting display device. The touch panel-integrated organic light emitting display device includes an upper substrate, a lower substrate and a touch panel positioned between the upper substrate and the lower substrate. The touch panel includes an array of first touch electrodes connected in a first direction under the upper substrate, an array of second touch electrodes, in a same plane as the first touch electrodes, connected in a second direction perpendicular to the first direction under the upper substrate, a plurality of connection electrodes connecting the second touch electrodes in the second direction, and at least one of the first and second touch electrodes includes a touch detection part and a floating part electrically isolated from the touch detection part.

Disclosed herein are a crosstalk canceling pattern for high-speed communications and a modular jack having the same, which includes a compensating capacitor on a transmission line to cancel crosstalk due to parasitic capacitance generated between neighboring insert pins, and includes a second compensating capacitor to correct phase mismatch due to parasitic inductance generated in insert pins and transmission lines, when a high-frequency signal is applied. The modular jack having the crosstalk canceling pattern for high-speed communications includes a housing, a printed circuit board, a lower contact block, and an upper contact block. The hosing includes a plug insert hole, an insert pin locking plate, and a coupling guide part. The printed circuit board is a multi-layered structure having a plurality of compensating capacitors. The lower contact block is mounted to the lower surface of the printed circuit board. The upper contact block is mounted to the upper portion of the lower contact block, and divides UTP cable wires to be connected to IDC terminals.

A method for creating a MEMS structure is provided. In accordance with the method, a substrate (53) is provided having a sacrificial layer (55) disposed thereon and having a layer of silicon (57) disposed over the sacrificial layer. A first trench (59) is created which extends through the silica layer and the sacrificial layer and which separates the sacrificial layer into a first region (61) enclosed by the first trench and a second region (63) exterior to the first trench. A first material (65) is deposited into the first trench such that the first material fills the first trench to a depth at least equal to the thickness of the sacrificial layer. A second trench (71) is created exterior to the first trench which extends through at least the silicon layer and exposes at least a portion of the second region of the sacrificial layer. The second region of the sacrificial layer is contacted, by way of the second trench, with a chemical etching solution adapted to etch the sacrificial layer, said etching solution being selective to the first material.

The present invention provides a display device including a pixel array section, the pixel array section having pixels arranged in a matrix form, each of the pixels including: an electro-optical element; a write transistor; a holding capacitance; a drive transistor; and a switching transistor; a write scan line disposed for each of pixel rows of the pixel array section and adapted to convey a write signal to be applied to the gate electrode of the write transistor; and a correction scan line, wherein the wiring structure of the write scan line does not intersect with the wiring pattern connected to the gate electrode of the drive transistor.

An in-plane switching mode liquid crystal display device includes first and second substrates, a gate line on the first substrate, a data line crossing the gate line defining a unit pixel region, a thin film transistor at the crossing of the gate line and the data line, a pixel electrode line in parallel with the data line, a plurality of pixel electrodes formed to be protruded in an extended direction of the gate line from the pixel electrode line, a common electrode line adjacent to a data line of a neighboring pixel in the extended direction of the gate line and in parallel therewith, a plurality of common electrodes protruded from the common electrode line and alternately arranged in parallel with the plurality of pixel electrodes to generate an in-plane electric field, and a liquid crystal layer between the first and second substrates.

A touch sensor panel includes at least one first electrode, and a second electrode above the at least one first electrode configured to cross the at least one first electrode, and having one or more openings therein.

The invention describes a novel test structure and process to create the structure for performing automatic dynamic stress testing of PMOS devices for Negative Bias Temperature Instability (NBTI). The invention consists of an integrated inverter, two integrated electronic switches for switching from stress mode to device DC characterization measurement mode, and a PMOS FET device under test (DUT). The inverter assures the proper 180 degree phase relationship between the test device source and gate voltage while the imbedded electronic switches provide isolation of the test device during DC characterization testing. Another embodiment of the invention enables the testing of multiple devices under test (DUT's).

A black matrix having an opening at pixels of a matrix array in a display area, a common wire including common pads and common signal lines, and gate pads in a peripheral area, and an alignment key in outer area to align interlayer thin films are formed on an insulating substrate. Red, blue and green color filters the edge of which overlap the black matrix are formed at the pixels on the insulating substrate, and an organic insulating layer covering the black matrix and the color filters and having a contact hole exposing the gate pad is formed thereon. A gate wire including a gate line connected to the gate pad through the contact hole and a gate electrode connected to the gate line is formed on the organic insulating layer, and a gate insulating layer covering the gate wire is formed on the organic insulating layer. A semiconductor pattern and ohmic contact layers are sequentially formed on the gate insulating layer of the gate electrode. A data wire including a source electrode and a drain electrode that are made of a same layer on the ohmic contact layers and separated from each other, and a data line connected to the source electrode and defining the pixels of a matrix array by crossing the gate line is formed on the gate insulating layer. A passivation layer covering the data wire and having contact holes exposing the gate pad and the data pad is formed, and a pixel wire including a pixel electrode, a redundant gate pad, a redundant data pad that are respectively connected to the drain electrode, the gate pad and the data pad through the contact holes.

A liquid crystal display includes a plurality of gate lines extending in a first direction to transmit gate signals and a plurality of data lines extending in a second direction to transmit data voltages. The data lines cross the gate lines. A plurality of thin film transistors are connected to the gate and the data lines, and a plurality of pixel electrodes are connected to the thin film transistors. A passivation layer is formed on the gate and the data lines. A shielding electrode extends along the gate and the data lines such that the shielding electrode overlaps the gate and the data lines, and the shielding electrode overlapping the gate line has a width larger than the width of the gate line. As the shielding electrode completely covers the data and the gate lines, the parasitic capacitance between the data and gate lines and the pixel electrode is reduced, thereby preventing deterioration of the display image quality.

In a method of forming a device isolation layer for minimizing a parasitic capacitor and a non-volatile memory device using the same, a trench is formed on a substrate. A first insulation layer is formed on a top surface of the substrate and on inner surfaces of the trench, so that the trench is partially filled with the first insulation layer. A second insulation layer is formed on the first insulation layer to a thickness to fill up the trench, thereby forming a preliminary isolation layer. An etching rate of the second insulation layer is different from that of the first insulation layer. A recess is formed at a central portion of the preliminary isolation layer by partially removing the first and second insulation layers, thereby forming the device isolation layer including the recess. The recess in the device isolation layer reduces a parasitic capacitance in a non-volatile memory device.

Methods of forming integrated circuit devices (e.g., memory devices) include the use of preferred self-aligned contact hole fabrication steps. These steps improve process reliability by reducing the likelihood that contact holes will become misaligned to underlying integrated circuit device structures and thereby potentially expose the structures in an adverse manner. Typical methods include the steps of forming a plurality of interconnection patterns on a substrate and then covering a surface of the interconnection patterns and a portion of the substrate with a capping insulating layer such as silicon nitride layer. The capping insulating layer is then covered with an upper interlayer insulating layer different from the capping insulating layer. The upper interlayer insulating layer and the capping insulating layer are then dry-etched in sequence to form a first narrow contact hole that exposes the substrate, but preferably does not expose the interconnection patterns. The first contact hole is then widened in a self-aligned manner using the capping insulating layer as an etch-stop layer. This widening step is performed by wet etching sidewalls of the first contact hole using an etchant that etches the upper interlayer insulating layer faster than the capping insulating layer. In this manner, the first contact hole may be formed to initially compensate for potential misalignment errors and then a self-aligned wet etching step may be performed to widen the first contact hole into a second contact hole so that low resistance contacts (e.g., contact plugs) can be provided therein.

An apparatus and method for a system with improved power supply rejection ratio (PSRR) over a wide frequency range. The improved PSRR is achieved by negating the influence of the parasitic capacitance associated with the bias lines and the introduction of a regulated power supply with embodiments associated with providing a ripple free and regulated supply. With reduction of parasitic capacitance, and providing an ENABLE switch by a pre-regulated supply, the degradation of the PSRR is achieved. The embodiments include both n-channel and p-channel MOSFETs implementations, and a positive and negative regulated power supply voltage. With the combined influence of the utilization of the VREG supply, and the lowering of battery-to-bias line capacitance using design layout and improved floor planning an improved PSRR over a wide frequency distribution is achieved.