Abstract: A tray is automatically mounted on a pallet. A tray handling device, which handles a tray collected from a component mounting device configured to mount a component held in a tray on a substrate, includes: a pallet collecting unit configured to take out a pallet on which the tray is mounted from a magazine collected from the component mounting device; and a tray unloading unit configured to unload the tray from the collected pallet.

Abstract: A plurality of display pixels each include: an organic EL element; a capacitance element that holds a first voltage used to cause the organic EL element to emit light; a drive transistor that supplies a current corresponding to the first voltage to the organic EL element; and a capacitance element that holds a second voltage that is a next voltage to be held in the capacitance element. A power line is connected to a drain electrode of the drive transistor or a cathode of the organic EL element. An adjustment unit adjusts the voltage applied to the power line to be lower than the predetermined voltage, when a total current of the plurality of display pixels in the case where a current corresponding to the second voltage is supplied to the organic EL element in each of the plurality of display pixels is greater than or equal to a threshold.

Abstract: A plurality of display pixels each include: an organic EL element; a capacitance element that holds a first voltage used to cause the organic EL element to emit light; a drive transistor that supplies a current corresponding to the first voltage to the organic EL element; and a capacitance element that holds a second voltage that is a next voltage to be held in the capacitance element. A power line is connected to a drain electrode of the drive transistor or a cathode of the organic EL element. An adjustment unit adjusts the voltage applied to the power line to be lower than the predetermined voltage, when a total current of the plurality of display pixels in the case where a current corresponding to the second voltage is supplied to the organic EL element in each of the plurality of display pixels is greater than or equal to a threshold.

Abstract: Image display quality of a plasma display apparatus is enhanced. For this purpose, the plasma display apparatus includes a number-of-sustain-pulses corrector for controlling the number of sustain pulses to be generated. The number-of-sustain-pulses corrector includes an all-cell light-emitting rate detection circuit (46), a partial light-emitting rate detection circuit (47), and a lookup table. The number-of-sustain-pulses corrector sets a correction coefficient that is read out from the lookup table in response to an all-cell light-emitting rate and a partial light-emitting rate as a first correction coefficient, and a recorrection coefficient that is based on the first correction coefficient. The number-of-sustain-pulses corrector adjusts the first correction coefficient and the recorrection coefficient, using an adjustment gain preset for each subfield in response to the magnitude of the luminance weight.

Abstract: The image display quality of the plasma display apparatus is improved. For this purpose, the plasma display apparatus corrects the number of generated sustain pulses in each subfield using a first correction coefficient that is read from look-up table (62) in response to the all-cell light-emitting rate and the partial light-emitting rates and a common correction coefficient. The apparatus adds preset offset value OFST to the all-cell light-emitting rate, multiplies the addition result by the number of sustain pulses in each subfield, and calculates the sum total of the multiplication results in one field period to calculate an estimated value of the power consumption in one field period. The apparatus sets the common correction coefficient so that the estimated value of the power consumption in one field period before the correction using the first correction coefficient and the common correction coefficient is equivalent to that after the correction.

Abstract: A scan-pulse generating circuit has a shift resister section that has 2N (i.e. twice the number of the driving-voltage waveforms) resisters and shifts the data of the resisters; an N-bit latching section that retains output from every other resister of 2N resisters of the shift resister section and generates N control pulses for generating scan pulses; and switching section that generates scan pulses according to N control pulses.

Abstract: The object is to provide a display device in which high-quality image display that is free from luminance nonuniformity can be obtained with a simplified structure. A magnitude of load corresponding to the light emission state of each pixel cell on a display line is measured for each display line based on a video signal, and correction of the luminance level according to the magnitude of load corresponding to the display line is conducted for the interval of the video signal corresponding to each display line.

Abstract: An improved driving device for a display panel. In the display panel, pixel cells serving as pixels are positioned in a plurality of display lines. The driving device drives the display panel according to pixel data derived from an input image signal. The display lines are divided into a plurality of display line groups, and each group includes a plurality of neighboring display lines. The driving device has a light emission driving circuit. This circuit causes the pixel cells in each of the neighboring display lines in the respective display line groups to emit light at different brightness levels based on weighting values assigned to the display lines. The weighting values are assigned to the display lines such that bias in brightness differences between the pixel cells positioned in neighboring display lines falls within a prescribed range for all neighboring display lines in the display panel.

Abstract: A driver device for a display panel. Pixel cells are arranged on respective display lines of the display panel. Each N adjacent display lines makes one display line group. N is an integer of two or more. The pixels in each display line group are driven to emit light at different luminance levels based on one of M different dither patterns. One of the M dither patterns is selected sequentially and in predetermined periods, and the selected dither pattern is used. M is less than N. In the dither processing, N different weighting values are allocated to the N display lines in the display line group, respectively.

Abstract: A method of grayscale-driving a display panel in accordance with pixel data derived from a video signal. The display panel includes a plurality of display lines, with a plurality of pixel cells serving as pixels being arranged on each display line. A display period of a single field of the video signal is divided into a plurality of subfields. The method includes dividing one subfield into M lower subfields. M is an integer greater than one. M groups of display lines are prepared by sequentially taking every M display lines from the display lines. First to Mth address steps are performed in the M lower subfields respectively and sequentially. Each address step sets the pixel cells belonging to the display lines of the display line group concerned, to a drive mode determined by the pixel data. A first light emission step is performed to cause the pixel cells whose drive mode is a lit mode, to emit light directly before or after the address step concerned. Another subfield is divided into N lower subfields.

Abstract: A device for driving a display panel, in which a predetermined number of continuous subfields in one field is each formed by M divided subfields and n display lines are divided into M display line groups for each display lines, data conversion is applied to pixel data corresponding to each of the M display line groups with a different conversion characteristic from each other, multi-gradation processing is applied to the pixel data subjected to the data conversion, and address scanning for changing each of the pixel cells from the lit mode to the unlit mode in accordance with the pixel data subjected to the multi-gradation processing is performed for each of the display line groups in each of the M divided subfields.

Abstract: Disclosed is a method of driving a display panel for displaying a halftone image of each of fields constituting a video signal, each field being composed of a plurality of subfields. This method detects a luminance distribution of the video signal, divides each of the fields into a first subfield group comprised of N subfields and a second subfield group comprised of M subfields (N, M are integers equal to or more than one), and displays the first subfield group with 2N gradation levels and the second subfield group with (M+1) gradation levels. The numbers N, M of subfields respectively allocated to the first and second subfield groups are set in accordance with the luminance distribution.

Abstract: Discharge cells are arranged in matrix form in the discharge space defined between a front glass substrate and a back glass substrate. Red, green and blue phosphor layers are formed individually in the discharge cells such that the phosphor layers formed in adjacent discharge cells in the column direction have different colors. One pixel consists of three adjacent discharge cells arranged in the row direction and respectively having the red phosphor layer, the green phosphor layer and the blue phosphor layer formed therein. The pixels are arranged in matrix form in the row direction and the column direction.

Abstract: The object is to provide a display device in which high-quality image display that is free from luminance nonuniformity can be obtained with a simplified structure. A magnitude of load corresponding to the light emission state of each pixel cell on a display line is measured for each display line based on a video signal, and correction of the luminance level according to the magnitude of load corresponding to the display line is conducted for the interval of the video signal corresponding to each display line.

Abstract: A display device with a dithering circuit is provided which can perform dithering on an input video signal without causing flicker and dither noise. A correction value is provided to reduce the difference (average error value) between an average value of brightness levels represented by pixel data corresponding to each of pixels in a pixel group and an average value of brightness levels represented by dither added pixel data corresponding to each of the pixels in the pixel group. This correction value is added to the dither added pixel data for correction. This prevents flicker from being produced even when the assignment of dither coefficients in the pixel group is changed in each field to reduce dither noise. Also provided is a gray scale processing system which can perform gray scale processing on an input video signal without causing problems such as flicker.

Abstract: A driver device for a display panel. Pixel cells are arranged on respective display lines of the display panel. Each N adjacent display lines makes one display line group. N is an integer of two or more. The pixels in each display line group are driven to emit light at different luminance levels based on one of M different dither patterns. One of the M dither patterns is selected sequentially and in predetermined periods, and the selected dither pattern is used. M is less than N. In the dither processing, N different weighting values are allocated to the N display lines in the display line group, respectively.

Abstract: A method of grayscale-driving a display panel in accordance with pixel data derived from a video signal. The display panel includes a plurality of display lines, with a plurality of pixel cells serving as pixels being arranged on each display line. A display period of a single field of the video signal is divided into a plurality of subfields. The method includes dividing one subfield into M lower subfields. M is an integer greater than one. M groups of display lines are prepared by sequentially taking every M display lines from the display lines. First to Mth address steps are performed in the M lower subfields respectively and sequentially. Each address step sets the pixel cells belonging to the display lines of the display line group concerned, to a drive mode determined by the pixel data. A first light emission step is performed to cause the pixel cells whose drive mode is a lit mode, to emit light directly before or after the address step concerned. Another subfield is divided into N lower subfields.

Abstract: An improved driving device for a display panel. In the display panel, pixel cells serving as pixels are positioned in a plurality of display lines. The driving device drives the display panel according to pixel data derived from an input image signal. The display lines are divided into a plurality of display line groups, and each group includes a plurality of neighboring display lines. The driving device has a light emission driving circuit. This circuit causes the pixel cells in each of the neighboring display lines in the respective display line groups to emit light at different brightness levels based on weighting values assigned to the display lines. The weighting values are assigned to the display lines such that bias in brightness differences between the pixel cells positioned in neighboring display lines falls within a prescribed range for all neighboring display lines in the display panel.

Abstract: A display device with a dithering circuit is provided which can perform dithering on an input video signal without causing flicker and dither noise. A correction value is provided to reduce the difference (average error value) between an average value of brightness levels represented by pixel data corresponding to each of pixels in a pixel group and an average value of brightness levels represented by dither added pixel data corresponding to each of the pixels in the pixel group. This correction value is added to the dither added pixel data for correction. This prevents flicker from being produced even when the assignment of dither coefficients in the pixel group is changed in each field to reduce dither noise. Also provided is a gray scale processing system which can perform gray scale processing on an input video signal without causing problems such as flicker.