Abstract: The present invention provides a touch-controlled display panel, which comprises an array substrate, a color filter substrate, and a liquid crystal layer disposed between the array substrate and the color filter substrate. The array substrate comprises a scan line, a data line, a pixel electrode, a first touch-controlled driving line, and a touch-controlled sensing line. The present invention further provides a touch-controlled display device. The present invention integrates the common line with the touch-controlled driving line and the touch-controlled sensing line, thereby improving the efficiency in manufacturing the touch-controlled display panel and reducing the manufacture cost thereof.

Abstract: A single layer capacitive touch module including a sensor clot matrix is disclosed. The sensor dot matrix has M×N sensor dots formed by M driving lines intersecting N sensing lines. Each one of the sensing lines and M driving lines forming a sensor zone, wherein each sensor zone comprises M sensor dots, M and N are positive integers. A driving unit coupled to the driving lines. A first soft board has a lead-in area on a first side thereof to be coupled with the driving lines on a first side of the sensor dot matrix. A second soft board having a lead-in area on a first side for being coupled with the driving lines and sensing lines on a second side of the sensor dot matrix opposite the first side of the sensor dot matrix.

Abstract: The present invention provides a touch-screen display device, which includes a liquid crystal display module, a first polarized film, a first sensor, wherein the first polarized film is disposed onto the liquid crystal display module, and the first sensor is dielectrically disposed onto the first polarized film. Wherein the liquid crystal display module includes a common electrode, a backlight module, a thin film transistor array substrate, a liquid crystal layer, and a color filter substrate, wherein the color filter is disposed onto the backlight module, and the thin film transistor array substrate is disposed under the first polarized film and above the color film substrate, the liquid crystal layer being arranged between the thin film transistor array substrate and the color filter substrate, and the common electrode being arranged between the liquid crystal layer and the thin film transistor array substrate.

Abstract: A computer device and frequency adjusting method for central processing unit are provided. The computer device including a CPU, a voltage regulator module, a clock generator, a power-on module, a chip set and an embedded controller. The power-on module activates the voltage regulator module, the clock generator and the CPU respectively. The voltage regulator module provides the operating voltage of the CPU. The clock generator provides the operating clock of the CPU. Before the CPU is activated, the embedded controller adjusts the operating clock and the operating voltage provided from the clock generator and the voltage regulator module the CPU, the CPU performs overclocking/downclocking directly by using the adjusted operating clock and the adjusted operating voltage after the CPU is activated.

Abstract: The invention discloses a single-layer capacitive touch unit, including a sensing electrode, connected to a control unit through a sensing electrode lead; and a plurality of scan electrodes, disposed at two sides of the sensing electrode; the scan electrode being connected to the control unit through a scan electrode lead, and the scan electrodes and the sensing electrode being coplanar; wherein one end of scan electrode lead connected to a second end of scan electrode and extending to near a next scan electrode to form extending lead; and the other end of scan electrode lead connected to the control unit. The invention also provides a capacitive touch screen with the capacitive touch unit. The invention can reduce the effect of noise signal on the touch signal and increase SNR of the touch signal.

Abstract: A display capable of providing 2D and/or 3D images. The display comprises a liquid crystal display device and a self-emissive display device. The self-emissive display device is disposed on the rear of the liquid crystal display device, in which the liquid crystal display device provides a first image and the self-emissive display device a second image and a backlight source. One of the first and second images comprises a parallax barrier pattern for forming a three-dimensional (3D) image, and the other is a 2D image.

Abstract: A computer device and frequency adjusting method for central processing unit are provided. The computer device including a CPU, a voltage regulator module, a clock generator, a power-on module, a chip set and an embedded controller. The power-on module activates the voltage regulator module, the clock generator and the CPU respectively. The voltage regulator module provides the operating voltage of the CPU. The clock generator provides the operating clock of the CPU. Before the CPU is activated, the embedded controller adjusts the operating clock and the operating voltage provided from the clock generator and the voltage regulator module the CPU, the CPU performs overclocking/downclocking directly by using the adjusted operating clock and the adjusted operating voltage after the CPU is activated.

Abstract: A LCD having multiple cell gaps and a method producing the same are provided. By stacking various numbers of dielectric layers and/or a photosensitive organic layer with various thicknesses on a display array substrate, various cell gaps for pixels of various colors can be obtained.

Abstract: A pixel structure of a transflective liquid crystal display array substrate includes a first patterned conductive layer, a second patterned conductive layer, a transparent patterned conductive layer, a passivation layer, and a patterned reflective metal layer. A first part of the second patterned conductive layer and a first part of the first patterned conductive layer form a first storage capacitor. The first part of the second patterned conductive layer and the transparent patterned conductive layer form a second storage capacitor. The passivation layer is formed to cover the patterned transparent conductive layer and has an opening to expose a part of the patterned transparent conductive layer. The patterned reflective metal layer is formed to cover the passivation layer and electrically connected with the patterned transparent conductive layer via the opening. A method for fabricating the pixel structure of the transflective liquid crystal display array substrate is also disclosed.

Abstract: A touch sensing substrate includes a substrate, first and second sensing series, a first dielectric layer, first and second dummy sensing series, a second dielectric layer, and a common electrode. The first sensing series are electrically insulated from each other, and so are the second sensing series. The first and the second sensing series are covered by the first dielectric layer. The first and the second dummy sensing series are disposed on the first dielectric layer. The first and the second dummy sensing series are disposed above the first and the second sensing series, respectively, and the dummy sensing series and the sensing series corresponding thereto have the same potential. The first and the second dummy sensing series are covered by the second dielectric layer. The common electrode is disposed on the second dielectric layer. A touch sensing liquid crystal display having the above-mentioned touch sensing substrate is also provided.

Abstract: A pixel structure of a transflective liquid crystal display array substrate includes a first patterned conductive layer, a second patterned conductive layer, a transparent patterned conductive layer, a passivation layer, and a patterned reflective metal layer. A first part of the second patterned conductive layer and a first part of the first patterned conductive layer form a first storage capacitor. The first part of the second patterned conductive layer and the transparent patterned conductive layer form a second storage capacitor. The passivation layer is formed to cover the patterned transparent conductive layer and has an opening to expose a part of the patterned transparent conductive layer. The patterned reflective metal layer is formed to cover the passivation layer and electrically connected with the patterned transparent conductive layer via the opening. A method for fabricating the pixel structure of the transflective liquid crystal display array substrate is also disclosed.

Abstract: A pixel structure of a transflective liquid crystal display array substrate includes a first patterned conductive layer, a second patterned conductive layer and a transparent patterned conductive layer. The first patterned conductive layer is formed on a substrate and includes a first part coupled to a pixel electrode voltage. The second patterned conductive layer includes a first part coupled to a common electrode voltage. The transparent patterned conductive layer is coupled to the pixel electrode voltage. The first part of the second patterned conductive layer and the first part of the first patterned conductive layer form a first storage capacitor. The first part of the second patterned conductive layer and the transparent patterned conductive layer form a second storage capacitor. A method for fabricating the pixel structure of the transflective liquid crystal display array substrate is also disclosed.

Abstract: A liquid crystal display device uses a first quarter-wave retardation film and a hybrid aligned nematic film to reduce light leakage in dark state for reaching high contrast ratio, and uses multiple-gamma IC to provide different gamma-curve signals for pixels of different colors to solve color shift problem. In addition, the liquid crystal display device may use a second quarter-wave retardation film to reduce light leakage when viewed in a wide angle so as to further provide higher contrast ratio.

Abstract: A LCD having multiple cell gaps and a method producing the same are provided. By stacking various numbers of dielectric layers and/or a photosensitive organic layer with various thicknesses on a display array substrate, various cell gaps for pixels of various colors can be obtained.

Abstract: A LCD having multiple cell gaps and a method producing the same are provided. By stacking various numbers of dielectric layers and/or a photosensitive organic layer with various thicknesses on a display array substrate, various cell gaps for pixels of various colors can be obtained.

Abstract: A memory controlling method adapted for driving a memory within a computer system is disclosed. When the computer system is booted, the memory is driven and tested via the BIOS. The memory controlling method performs tests on multiple controlling signals of the memory. The memory controlling method includes steps of: detecting an active window of each controlling signal; determining whether the active windows is larger than a predetermined window; performing a parameter adjustment on the controlling signals if one of the active windows is smaller than the predetermined window; performing a phase range test between two of the control signals if the active windows are larger than the predetermined window; performing a phase adjustment on the active windows of the controlling signals if the controlling signals fails in the phase range test; and driving the memory according to the adjusted controlling signals.

Abstract: A controllable power supply device with a step-up function including a constant voltage generator, a programmable voltage generator, a first switch and a linear regulator is provided. The constant voltage generator is used to provide an initial voltage. The programmable voltage generator is used to receive the initial voltage and adjust the received initial voltage to boost the initial voltage to a power supply voltage. The first connecting terminal of the first switch is used to receive the initial voltage, the second connecting terminal of the first switch is used to receive the power supply voltage, and the third connecting terminal of the first switch is coupled to one of the first connecting terminal and the second connecting terminal. Therefore, the voltage from the third connecting terminal of the first switch is stabilized and is outputted as the output voltage of the controllable power supply device by the linear regulator.

Abstract: A liquid crystal display device uses a first quarter-wave retardation film and a hybrid aligned nematic film to reduce light leakage in dark state for reaching high contrast ratio, and uses multiple-gamma IC to provide different gamma-curve signals for pixels of different colors to solve color shift problem. In addition, the liquid crystal display device may use a second quarter-wave retardation film to reduce light leakage when viewed in a wide angle so as to further provide higher contrast ratio.

Abstract: A touch sensing substrate includes a substrate, first and second sensing series, a first dielectric layer, first and second dummy sensing series, a second dielectric layer, and a common electrode. The first sensing series are electrically insulated from each other, and so are the second sensing series. The first and the second sensing series are covered by the first dielectric layer. The first and the second dummy sensing series are disposed on the first dielectric layer. The first and the second dummy sensing series are disposed above the first and the second sensing series, respectively, and the dummy sensing series and the sensing series corresponding thereto have the same potential. The first and the second dummy sensing series are covered by the second dielectric layer. The common electrode is disposed on the second dielectric layer. A touch sensing liquid crystal display having the above-mentioned touch sensing substrate is also provided.

Abstract: A display and a display method thereof are provided. The display is used for displaying 2D and/or 3D video image. The display method includes displaying 2D video image according to a first gamma curve and displaying 3D video image according to a second gamma curve, wherein the gamma value of the first gamma curve is greater than the gamma value of the second gamma curve.