A touch screen display may include gate line driver circuitry coupled to a display pixel array. The display may be provided with intra-frame pausing (IFP) capabilities, where touch or other operations may be performed during one or more intra-frame blanking intervals. In one suitable arrangement, a gate driver may be operable in a high impedance mode, where the output of the gate driver is left floating during touch or IFP intervals. In another suitable arrangement, the gate driver may be operable in an IFP reduced stress mode, where a digital pass gate in the gate driver is deactivated during IFP intervals. In yet another suitable arrangement, the gate driver may be operable in an all-gate-high (AGH) power-down mode, where the output of each gate driver in the driver circuitry is driven high in parallel when the displayed is being powered off. These arrangements may be implemented in any suitable combination.

A high-power power supply for use with display devices and an associated display device are provided. The high-power power supply includes an AC conversion module configured to rectify an external AC source into a DC output, a power factor correction circuit configured to perform power factor correction to the DC output and output a correction completion signal when the correction is completed, a power-on control circuit configured to control the power factor correction circuit to be turned on to perform the power factor correction to the DC current when receiving a power-on signal and to control multiple resonance control circuits to be turned on when receiving the correction completion signal, a plurality of resonance control circuits configured to, when turned on, control multiple transformers to operate normally, and multiple transformers configured to supply different operating voltages to the display device. The present disclosure has the advantage of low cost.

A display device includes a plurality of pixels on a substrate, each of the plurality of pixels including a pixel circuit to drive a plurality of light emitting elements, wherein the pixel circuit of each of the plurality of pixels includes: a first transistor configured to supply a driving current to a first electrode of the light emitting elements; and a plurality of light emitting groups, each of the light emitting groups including some of the light emitting elements and a bypass unit connected between the first electrode and a second electrode of the some of the light emitting elements to selectively bypass a part of the driving current.

A display apparatus includes a display, a loudspeaker and a controller. The controller is configured to: perform, based on one or both of (i) image information of an image that is displayed on the display, and (ii) sound information of sound that is output from the loudspeaker, electric current control processing that controls a sum of an electric current to be supplied to the display and an electric current to be supplied to the loudspeaker.

A display device may include a display panel which displays an image based on a data voltage, a driving controller including a net power control setter which determines a scale factor for adjusting a gray scale of (N+1).sup.th frame data based on a load of N.sup.th frame data and a net power control reference value, where the driving controller generates a data signal based on input image data, and N is a natural number greater than or equal to 2, a data driver which converts the data signal into the data voltage and outputs the data voltage to the display panel, and a power supply voltage generator which senses a power supply current applied to the display panel in an N.sup.th frame and generates a power supply voltage based on a current level of the power supply current.

A display apparatus includes a plurality of light emitting elements, at least one common line, a power supply, a plurality of drive lines, and a controller. The at least one common line is connected to first ends of the plurality of light emitting elements. The plurality of drive lines are connected to second ends of the plurality of light emitting elements. The controller is to execute delay control on lighting possible periods in which the plurality of light emitting elements are to light in unit delay control periods so that an order of delaying the lighting possible periods in a single unit delay control period among the unit delay control periods is different from an order of delaying the lighting possible periods in any one of the unit delay control periods other than the single unit delay control period.

A data processing device based on a programmable logic device is described that includes at least one function circuit configured to process input data; and at least one current smoothing circuit, each corresponding to one of the at least one function circuit, and configured to smooth a current change of the programmable logic device caused when a corresponding function circuit is switched between on and off. The current smoothing circuit includes a control circuit configured to generate a driving signal based on a switching manner of the function circuit corresponding to the current smoothing circuit; and a redundant circuit configured to operate according to the driving signal to smooth the current change. The control circuit includes a decoding control word generating circuit and a decoding circuit.

An information display device includes a display that displays information, a communication unit that contactlessly communicates with an information communication medium, a communication control unit including a transceiver and a power converter such that the transceiver receives the display information from the information communication medium through the communication unit and that the power converter converts an electromagnetic wave received by the communication unit into electric power, and a display control unit including a storage, a voltage monitor, and a display driver such that the storage stores the display information received by the transceiver, that the voltage monitor monitors a voltage of electric power supplied from the power converter, and that the display driver updates, based on the display information stored in the storage, the information displayed on the display.

A burning protection circuit of a display device includes a plurality of current measuring units and a control unit. The display device includes a plurality of pixel blocks. Each of the pixel blocks includes a plurality of pixels. The pixel blocks are respectively supplied with power through a plurality of power supply lines. The current measuring units are configured to respectively generate a plurality of measured current values by respectively measuring a plurality of currents respectively supplied to the pixel blocks through the power supply lines. The control unit is configured to respectively generate a plurality of block data for the pixel blocks based on pixel data for the pixels of corresponding ones of the pixel blocks, and determine whether an overcurrent occurs based on a plurality of ratios of the measured current values to corresponding ones of the block data.

A display apparatus comprises a display panel including a plurality of data lines and a plurality of gate lines, a data driver circuit configured to convert image data to a grayscale voltage and to output the grayscale voltage to a data line, a voltage generator configured to provide the data driver circuit to a driving voltage, and a heat blocking circuit configured to compare a load current voltage with a reference voltage and to output a control signal for controlling the data driver circuit, the load current voltage being proportionate to a load current flowing toward the data driver circuit.