Abstract: The present invention relates to methods and compositions for identifying, selecting and/or producing a pathogen resistant plant or germplasm (e.g., soybean plant or germplasm) using genes derived from Glycine tomentella. Candidate genes capable of conferring pathogen resistance (e.g., to Asian Soy Rust) are provided. A plant or germplasm that has been identified, selected and/or produced by any of the methods of the present invention is also provided. Pathogen resistant seeds, plants and germplasms are also provided.

Abstract: The present invention provides compositions, systems, and methods for conferring resistance to plant pathogens that express pathogen-specific proteases. Compositions of the invention may include a recombinant nucleic acid molecule comprising a promoter operably linked to a nucleotide sequence that encodes at least one substrate protein of a plant pathogen-specific protease expressed by a Phakopsora or Heterodera plant pathogen species. Additionally, the at least one substrate protein has a Phakopsora-specific or Heterodera-specific heterologous cleavage site, wherein cleavage of the cleavage site confers improved resistance to the Phakopsora or Heterodera plant pathogen species.

Abstract: The present invention relates to methods and compositions for identifying, selecting and/or producing a Disease resistant soybean plant or germplasm using markers, genes and chromosomal intervals derived from Glycine tomentella PI441001, PI441008, PI446958, PI583970, or PI483224. A soybean plant or germplasm that has been identified, selected and/or produced by any of the methods of the present invention is also provided. Disease resistant soybean seeds, plants and germplasms are also provided.

Abstract: The present invention relates to methods and compositions for identifying, selecting and/or producing a Disease resistant soybean plant or germplasm using markers, genes and chromosomal intervals derived from Glycine tomentella PI441001, PI441008, PI446958, PI583970, or PI483224. A soybean plant or germplasm that has been identified, selected and/or produced by any of the methods of the present invention is also provided. Disease resistant soybean seeds, plants and germplasms are also provided.

Abstract: The present invention relates to methods and compositions for identifying, selecting and/or producing a Disease resistant soybean plant or germplasm using genes derived from Glycine canescens, Glycine clandestina, Glycine tomentella. A soybean plant or germplasm that has been identified, selected and/or produced by any of the methods of the present invention is also provided. Disease resistant soybean seeds, plants and germplasms are also provided.

Abstract: The present invention relates to methods and compositions for identifying, selecting and/or producing a Disease resistant soybean plant or germplasm using genes derived from wild Glycine. A soybean plant or germplasm that has been identified, selected and/or produced by any of the methods of the present invention is also provided. Disease resistant soybean seeds, plants and germplasms are also provided.

Abstract: A display panel and a display comprising the display panel. The display panel comprises a primary display area (190) and a secondary display area (290); a first gate driving unit (121) for display driving is provided in the primary display area (190), and a second gate driving unit (122) for display driving is provided in the secondary display area (290); a via hole (181) is formed in the secondary display area (290); at least a portion of the secondary display area (290) is configured to display an image together with at least a portion of the primary display area (190). The display panel increases the screen-to-body ratio and is more attractive.

Abstract: A method for driving touch display and a touch display screen are provided. The touch display screen includes a plurality of continuous work time periods. Each work time period includes a display time period and a touch time period. In the display time period, a plurality of second signal lines are configured to cooperate with a plurality of third signal lines to perform image-signal transmission for image display. The touch time period includes a detection time period and a sensing time period. In the detection time period, at least one second signal line of the plurality of the second signal lines is provided with a touch driving signal, a detection signal is received from a plurality of first signal lines, the detection signal is compared with a preset signal to obtain a comparison result, the touch time period is prolonged or shortened according to the comparison result.

Abstract: A display panel and an image data compensation method thereof are provided. The display panel includes a first data driving module and a second data driving module. The first data driving module is configured to provide image data signals for a first display area and perform De-Mura compensation. The second data driving module is configured to provide image data signals for a second display area and perform De-Mura compensation. The first data driving module is configured to obtain image data of the second display area after De-Mura compensation, and adjust image data of a first compensation area adjacent to the second display area in the first display area. The second data driving module is configured to obtain image data of the first display area after De-Mura compensation, and adjust image data of a second compensation area adjacent to the first display area in the second display area.

Abstract: A display panel and an image data compensation method thereof are provided. The display panel includes a first data driving module and a second data driving module. The first data driving module is configured to provide image data signals for a first display area and perform De-Mura compensation. The second data driving module is configured to provide image data signals for a second display area and perform De-Mura compensation. The first data driving module is configured to obtain image data of the second display area after De-Mura compensation, and adjust image data of a first compensation area adjacent to the second display area in the first display area. The second data driving module is configured to obtain image data of the first display area after De-Mura compensation, and adjust image data of a second compensation area adjacent to the first display area in the second display area.

Abstract: A method for driving touch display and a touch display screen are provided. The touch display screen includes a plurality of continuous work time periods. Each work time period includes a display time period and a touch time period. In the display time period, a plurality of second signal lines are configured to cooperate with a plurality of third signal lines to perform image-signal transmission for image display. The touch time period includes a detection time period and a sensing time period. In the detection time period, at least one second signal line of the plurality of the second signal lines is provided with a touch driving signal, a detection signal is received from a plurality of first signal lines, the detection signal is compared with a preset signal to obtain a comparison result, the touch time period is prolonged or shortened according to the comparison result.

Abstract: The present invention relates to methods and compositions for identifying, selecting and/or producing a Disease resistant soybean plant or germplasm using markers, genes and chromosomal intervals derived from Glycine tomentella PI441001, PI441008, PI446958, PI583970, or PI483224. A soybean plant or germplasm that has been identified, selected and/or produced by any of the methods of the present invention is also provided. Disease resistant soybean seeds, plants and germplasms are also provided.

Abstract: A method for rendering pixel, an apparatus for rendering pixel, and a display device are disclosed. The method includes steps of obtaining gray-scale values of three primary colors of an original image pixel in an RGB color space, converting the gray-scale values of three primary colors of the original image pixel into gray-scale values of three primary colors and a compensating component of a compensating image pixel, sampling from a compensating image, and setting the gray-scale values of the three primary colors and the compensating component of two adjacent compensating image pixels in each row as gray-scale values of corresponding sub pixels of a screen pixel in each row.

Abstract: A driving circuit for a display panel is disclosed. The driving circuit includes at least a driving signal line connected to a display driving signal transmission unit delivering display driving signal produced by the display driving signal transmission unit to sub-pixels of the display panel through the driving signal line; and a number of data signal lines connected to a display data provision unit delivering display data signal produced by the display data provision unit to the sub-pixels. For each subset of the sub-pixels that are of a same component color, at least two data signal lines, starting from different points of time, deliver display data signal to the subset of sub-pixels that are of the same component color. The driving circuit effectively resolves glitches to input signal resulted from heavy transient load to the input signal.

Abstract: The present disclosure relates to a driving system of display panels. The driving system includes a main board and a display panel. The main board is configured with a driving chip, and the driving chip electrically connects to the display panel via a flexible circuit board to drive the display panel to display. With such configuration, the driving system is configured with the main board and the driving chip, and the driving chip is arranged on the main board, instead of the flexible circuit board. With such configuration, the space of the display area occupied by the components is reduced so as to realize the narrow border design for a top border and a bottom border of the display panel. In this way, the screen ratio of the display panel is increased.

Abstract: The present application discloses a bilateral driving device and a tablet display. The bilateral driving device includes a first source driver, a second source driver and at least two driving signal lines connected to the first source driver, a second source driver, wherein the connection of the middle site of the at least two driving signal lines is not parallel to the specific edge of the display panel. By adapting the embodiment of the present application can utilize the visual characteristics of the human eye, the connection of the middle site of the at least two driving signal lines is not parallel to the edge of the display panel to confuse the dark spots and bright spots, to enhance brightness uniformity of the display panel, and improve the display quality.

Abstract: The present disclosure relates to a driving method and a driving device of display panels. The driving method includes: obtaining three-color sub-pixel data of each of pixels of a current image, obtaining a saturation value corresponding to each of the pixels in accordance with the three-color sub-pixel data of each of the pixels, obtaining a current background-white ratio in accordance with the three-color sub-pixel data and the saturation value of each of the pixels, determining whether the current background-white ratio is within a predetermined adjustment range, and reducing a white grayscale value of four-color sub-pixel data of the current image in accordance with the current background-white ratio and outputting the reduced white grayscale value to a display panel. In this way, the darker pure-color effect due to the high contrast may be reduced, which effectively enhances the darker pure-color issue of the RGBW display panel.

Abstract: The present disclosure relates to a driving method and a driving device of display panels. The driving method includes: dividing a saturation interval of an original image frame to be displayed by a display panel into a plurality of sub-saturation intervals; obtaining saturation values corresponding to each of the pixels in the original image frame; calculating numbers of pixels in the original image frame falling within each of the sub-saturation intervals in accordance with the saturation values corresponding to each of the pixels. In this way, the backlight brightness outputted by the backlight module may be adjusted in accordance with the saturation values of the original image frame so as to enhance the low brightness issue when a pure-color image is displayed by the display panel configured with RGBW sub-pixels.

Abstract: The present disclosure relates to a display panel and an array substrate including a plurality of pixel cells including colorful sub-pixels and one white sub-pixel. Each of the sub-pixels includes at least one sub-pixel electrode and at least one sub-pixel transistor corresponding to each of the sub-pixel electrode. The sub-pixel transistors are configured within the white sub-pixel to enhance an aperture rate of the colorful sub-pixels. As the sub-pixel transistors are configured within the same white sub-pixel, the brightness of the white sub-pixel may be decreased. At the same time, the aperture rate of the colorful sub-pixels may be greatly enhanced so as to enhance the performance of colorful images.

Abstract: A touch driving circuit and a touch sensitive display panel are provided. The touch driving circuit is disposed on a corresponding touch sensitive display panel. The touch driving circuit includes a touch driving chip, driving signals encoders, driving lines, sensing lines, driving wires, and sensing wires. Preliminary touch driving signals herein include touch data signals and touch clock signals, and the driving signals encoders convert the touch data signals into the touch driving signals according to the touch clock signals.