31results about How to "Prevent image quality degradation" patented technology

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.

Discussed are an apparatus and method for driving a liquid crystal display device, whereby the apparatus includes a data driver for driving data lines of a liquid crystal panel, setting detectable temperatures for different temperature detection time points, detecting an ambient temperature at each temperature detection time point, and outputting a gate drive voltage variation signal and a common voltage variation signal in accordance with the set and detected temperatures at each temperature detection time point, and a power supplier for varying levels of a gate drive voltage and a common voltage in accordance with the gate drive voltage variation signal and the common voltage variation signal, and supplying the gate drive voltage and common voltage to a gate driver and the liquid crystal panel, respectively.

A liquid crystal display includes a liquid crystal display panel having a plurality of data lines, a plurality of gate lines, and a plurality of liquid crystal cells, a timing controller to determine gray levels of input digital video data and a time at which a polarity of a data voltage to be supplied to the data lines is inverted and generate a dynamic charge share control signal to indicate a time at which the gray level of the data voltage is changed from a white gray level to a black gray level and a time at which the polarity of the data voltage is inverted, and to detect weakness patterns in which the data of the white gray level and the black gray level are regularly arranged in the input digital video data and generate a dot inversion control signal for widening a horizontal polarity inversion time of data voltages to be supplied to the data lines when the weakness patterns are input, a data driving circuit to convert the digital video data from the timing controller into the data voltage, change the polarity of the data voltage, supply any one of a common voltage and a charge share voltage between a positive data voltage and a negative data voltage to the data lines in response to the dynamic charge share control signal, and widen the horizontal polarity inversion time of the data voltages in response to the dot inversion control signal, and a gate driving circuit to sequentially supply a scan pulse to the gate lines under the control of the timing controller, wherein the liquid crystal display panel includes first and second liquid crystal cell groups whose polarity is inverted every 2 frame periods, and a polarity inversion time of the first liquid crystal cell group and a polarity inversion time of the second liquid crystal cell group overlap.

Disclosed herein is a driving apparatus for driving a pixel, including a first pMOS type transistor connected to a first potential a first nMOS type transistor connected in series to the first pMOS type transistor and connected to a second potential; and a control section configured to control the first pMOS type transistor and the first nMOS type transistor individually using a first on-signal for controlling the timing of turning on of one of the first pMOS type transistor and the first nMOS type transistor; a signal of a potential at a node between the first pMOS type transistor and the first nMOS type transistor being inputted as a driving signal for driving the pixel to the pixel.

A liquid crystal display device including a gate line formed on a first substrate; first and second adjacent data lines crossing the gate line to form adjacent pixel regions in an extended direction of the gate line; only one pixel electrode line in parallel with the first data line in each of the pixel regions; a plurality of pixel electrodes formed to be protruded in the extended direction of the gate line from the pixel electrode line; a plurality of common electrodes alternately formed in parallel with the plurality of pixel electrodes and generating an in-plane electric field therebetween; and an alignment film having a rubbing direction perpendicular to the first data line.

A liquid crystal display device includes a gate line formed on a substrate; first and second data lines crossing the gate line to form adjacent pixel regions in a direction of the gate line; pixel electrodes and common electrodes substantially parallel to each other and generating an in-plane electric field; a first pixel electrode line parallel to the first data line and spaced apart from the first data line by a first isolation distance; a second pixel electrode line spaced apart from the second data line by a second isolation distance; and a first common line parallel to the first data line and spaced apart from the first data line by a third isolation distance; a second common line spaced from the second data line by a fourth isolation distance, wherein the first isolation distance is shorter than the third isolation distance, and a parasitic capacitance between the first pixel electrode line and the first data line is greater than a parasitic capacitance between the second pixel electrode line and the second data line.

A liquid crystal display (LCD) device and driving method for same is disclosed. The liquid crystal display device included: a plurality of pixel cells formed at pixel regions defined by crossings of a plurality of gate and data lines on a substrate, each pixel cell for displaying one of three colors, wherein the pixel cells are arranged with pixel cells of a single color arranged along the each gate line, and pixel cells of the three colors are alternately arranged along each data line; a gate built-in circuit built on the substrate that sequentially drives the gate lines; and a driving integrated circuit formed on the liquid crystal panel, that drives the gate built-in circuit and that modulates a video signal to be supplied to the data lines in response to an ambient temperature of the liquid crystal panel.

An in-plane switching (IPS) liquid crystal mode liquid crystal display device that prevents signal interference of a data line and disclination is disclosed. The in-plane switching (IPS) mode liquid crystal display (LCD) device includes first and second substrates; a gate line on the first substrate; a data line crossing the gate line to form a pixel region; a thin film transistor at the crossing of the gate line and the data line; a plurality of pixel electrodes and common electrodes alternately arranged in parallel in an extended direction of the gate line and generating an in-plane field of a first direction; an alignment film rubbed in a direction substantially perpendicular to the data line; and a liquid crystal layer between the first and second substrates, wherein the pixel electrode and the common electrode are bent at both ends thereof and the in-plane field in the first direction is generated from both ends of the pixel electrode and the common electrode.

Disclosed is a compensation circuit for a common voltage according to a gate voltage, which compensates the common voltage in accordance with variation in gate high voltage, to obtain an optimal common voltage. The compensation circuit includes a divider to divide a gate high voltage, an adder to add a fed-back common voltage to a voltage output from the divider, and a differential amplifier to differentially amplify a voltage output from the adder, and to output the amplified voltage as a compensated common voltage.

The invention discloses a zoom processing method, a device, a readable storage medium and a mobile terminal. The zoom processing method comprises the following steps: when a zoom instruction for an original preview image of a camera is received, the zoom multiple in the zoom instruction is obtained; when the zoom instruction is received, the zoom multiple in the zoom instruction is obtained; whenthe zoom instruction is received, the zoom multiple is obtained. Increasing a pixel matrix of the original preview image to obtain a first preview image; enlarging the size of the first preview imageby the zoom multiple to obtain a second preview image; an image of a preset size is intercepted in the second preview image as a zoomed preview image. The invention can ensure that the image quality is still high after zooming, and improves the photographing experience of the user. In addition, the invention does not need too many algorithms, and the data processing quantity is small and the timeconsuming is short, so the invention is more practical.

It is an object of the present invention to provide special effects which will make a video game more realistic. When a virtual light source exists in a three-dimensional virtual space, if a light from the light source extends toward a camera, a flare is generated on a screen because of incidence of the ray of light into a camera lens, thereby forming a dazzling picture in accordance with the state of backlight.

A liquid crystal display includes a liquid crystal display panel, a timing controller to generate a dynamic charge share control signal to indicate a time at which the gray level of a data voltage is changed from a white gray level to a black gray level and a time at which the polarity of the data voltage is inverted, and to detect weakness patterns and generate a dot inversion control signal for widening a horizontal polarity inversion time of data voltages when the weakness patterns are input, wherein the liquid crystal display panel includes first and second liquid crystal cell groups whose polarity is inverted every 2 frame periods, and a polarity inversion time of the first liquid crystal cell group and a polarity inversion time of the second liquid crystal cell group overlap.

A semiconductor device has a multiplicity of DAC channels for performing digital-to-analog conversion of video signals. Signal processing means for delaying processing of signals by a predetermined delay time is provided in at least one DAC channel. The signal processing means functions as a phase inversion means to reduce cross talks between the DAC channels. The signal processing means also functions as a delay circuit to reduce voltage fluctuations in the power supply.

A liquid crystal display device including a gate line formed on a first substrate; first and second adjacent data lines crossing the gate line to form adjacent pixel regions in an extended direction of the gate line; only one pixel electrode line in parallel with the first data line in each of the pixel regions; a plurality of pixel electrodes formed to be protruded in the extended direction of the gate line from the pixel electrode line; a plurality of common electrodes alternately formed in parallel with the plurality of pixel electrodes and generating an in-plane electric field therebetween; and an alignment film having a rubbing direction perpendicular to the first data line.

A liquid crystal display device adopting a storage-on-common method is disclosed to prevent the operation of a unit pixel with a point deficiency, such as a brilliant spot, at its occurrence, thereby preventing degradation of a picture quality caused due to the defective pixel. Because the defective pixel is controlled to turn black by the use of a repair pattern, the picture quality degradation due to the defective pixel is prevented when the liquid crystal display device is driven.

The present invention is directed to a liquid discharge apparatus adapted for discharging inks from discharge holes, which comprises a control unit (68) for controlling a discharge control unit (63), wherein the control unit controls the discharge control unit in such a manner that pulse current delivered to one of a pair of heating resistors (42a), (42b) is caused to be reference, and pulse current is delivered to the other heating resistor in the state where timing is shifted in a time of the range within 20% of supply time of pulse current serving as reference with respect to supply timing of pulse current serving as reference. Thus, it is possible to suppress unevenness or variation of impact positions of ink droplets discharged in the state where discharge direction has been changed. As a result, deterioration of picture quality resulting from color tone unevenness and / or white stripe, etc. is prevented. Thus, print operation can be performed at excellent picture quality.

When a trapping process is applied to data which are subdivided upon conversion from application data into PDL data or conversion from PDL data into intermediate data, the trapping process is applied to all subdivided objects. As a result, the trapping process brings about image quality drop. Hence, a clustering server receives PDL data, analyzes the PDL data to generate intermediate data and meta data, executes an object combining process with reference to the meta data, executes a trapping former half process, and transmits only the intermediate data to a printing server. A printing server applies a trapping latter half process to the received intermediate data.

An organic light emitting display that is capable of preventing degradation of picture quality, and a method of manufacturing the organic light emitting display are provided. A unit pixel for the organic light emitting display, includes a first transistor coupled to a data line and having a first voltage threshold, a second transistor coupled to the first and third transistors and controlled by a second select signal, a third transistor coupled to the first transistor and controlled by a first select signal, and a fourth transistor coupled to the third transistor and having a fourth voltage threshold such that a drive current of the fourth transistor is controlled independent of the fourth voltage threshold.

A plurality of painting zones is connected in series by a plurality of air exhaust ducts so as to allow air to flow through the painting zones. A paint mist in air having passed through a painting chamber of each painting zone is removed by a dry filter. Feedback control is performed on the temperature and the humidity of air in a second painting zone other than a third painting zone to which conditioned air from an air conditioner is supplied. Thus, it is possible to appropriately adjust the temperature and the humidity of each painting zone and avoid degradation of painting quality in each painting zone, while achieving downsizing of the entire system by not providing a recycling air conditioner on the route of an air flow passage.

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.

An in-plane switching (IPS) liquid crystal mode liquid crystal display device that prevents signal interference of a data line and disclination is disclosed. The in-plane switching (IPS) mode liquid crystal display (LCD) device includes first and second substrates; a gate line on the first substrate; a data line crossing the gate line to form a pixel region; a thin film transistor at the crossing of the gate line and the data line; a plurality of pixel electrodes and common electrodes alternately arranged in parallel in an extended direction of the gate line and generating an in-plane field of a first direction; an alignment film rubbed in a direction substantially perpendicular to the data line; and a liquid crystal layer between the first and second substrates, wherein the pixel electrode and the common electrode are bent at both ends thereof and the in-plane field in the first direction is generated from both ends of the pixel electrode and the common electrode.

The invention discloses a method and device for improving the definition of an ultra-high-definition 4K-resolution VR video, and the method comprises the steps: setting a hotspot spherical surface anda non-hotspot spherical surface on a spherical VR video, enabling the spherical VR video to be unfolded into a rectangular VR video with the resolution of M * H, and enabling the hotspot spherical surface and the non-hotspot spherical surface to be respectively mapped to a hotspot region and a non-hotspot region of the rectangular VR video; processing the resolution of the picture of the non-hotspot area to obtain a rectangular VR video with the resolution of N * H; and reversely carrying out the above steps to recover and obtain the spherical VR video. According to the method, the space withthe ultra-high-definition resolution is fully utilized, a spherical VR video with the equator resolution higher than 3840 can be supported, and the spherical effective information is increased; the method can be seamlessly compatible with equipment with various standard ultra-high-definition resolutions; only the width of the non-hotspot spherical surface is slightly scaled, so the extra distortion and the image quality reduction degree caused by a full-image stretching or compressing mode are remarkably reduced, and the performance consumption of image rendering is remarkably reduced; and the coherence of the original spherical picture is not damaged.