There is provided a display device including: an input unit used to input a plurality of image signals from a plurality of external apparatuses; a display unit which displays images; a setting unit which sets a display condition of each of the plurality of images based on an aspect ratio corresponding to each of the plurality of image signals input through the input unit; and a display control unit which generates a composite image from the plurality of image signals input through the input unit based on the contents set by the setting unit, and displays the composite image on the display unit.

There is provided a display device including: an input unit used to input a plurality of image signals from a plurality of external apparatuses; a display unit which displays images; a setting unit which sets a display condition of each of the plurality of images based on an aspect ratio corresponding to each of the plurality of image signals input through the input unit; and a display control unit which generates a composite image from the plurality of image signals input through the input unit based on the contents set by the setting unit, and displays the composite image on the display unit.

Tools and techniques are described to render oversize glyphs in a monospace grid. Glyph rendering algorithms collect changed cells, collect affected cells based on overlap, clear certain affected cells, and redraw only specified cells. By reducing the number of cells whose glyphs are redrawn in response a text edit, algorithms permit faster execution even when rendering is done by a script rather than precompiled code. Algorithmic advances also permit faster display frame rates, and help preserve battery power. Grids may be numbered, and traversed, in different ways. Oversize glyphs may include underscores, ligatures, mathematical symbols, emojis, kanji, accented characters in various natural languages, and wide or tall text characters which extend beyond the display space of a single cell. Glyph rendering may provide user interface updates in browsers, shells, terminal emulators, and other programs.

Tools and techniques are described to render oversize glyphs in a monospace grid. Glyph rendering algorithms collect changed cells, collect affected cells based on overlap, clear certain affected cells, and redraw only specified cells. By reducing the number of cells whose glyphs are redrawn in response a text edit, algorithms permit faster execution even when rendering is done by a script rather than precompiled code. Algorithmic advances also permit faster display frame rates, and help preserve battery power. Grids may be numbered, and traversed, in different ways. Oversize glyphs may include underscores, ligatures, mathematical symbols, emojis, kanji, accented characters in various natural languages, and wide or tall text characters which extend beyond the display space of a single cell. Glyph rendering may provide user interface updates in browsers, shells, terminal emulators, and other programs.

A display device includes a timing controller, a driver, and a display panel. The timing controller outputs a first clock signal having first rising time during an active section and a second clock signal having second rising time during a blank section adjacent to the active section. The driver generates a data signal based on the first clock signal and the second clock signal and to output the data signal. The display panel displays an image based on the data signal. The first rising time is shorter than the second rising time.

A display device includes a timing controller, a driver, and a display panel. The timing controller outputs a first clock signal having first rising time during an active section and a second clock signal having second rising time during a blank section adjacent to the active section. The driver generates a data signal based on the first clock signal and the second clock signal and to output the data signal. The display panel displays an image based on the data signal. The first rising time is shorter than the second rising time.

The present invention relates to an image display apparatus including a panel having repeatedly arranged RGBW subpixels and pixels including a first pixel, second pixel and third pixel, each having at least three subpixels and the first and third pixels being disposed immediately adjacent to the left and right sides of the second pixel; a controller for applying, to the subpixels of the first or third pixel, data corresponding to a subpixel of a color not included in the second pixel. When the luminance level of the second pixel is lower than a first reference level and luminance difference between the first and second pixels or between the second and third pixels is greater than a second reference level, the controller may not apply the data to subpixels of the first or third pixel. Thus, on the RGBW type panel, sharpness of the edge area can be improved.

The present invention relates to an image display apparatus including a panel having repeatedly arranged RGBW subpixels and pixels including a first pixel, second pixel and third pixel, each having at least three subpixels and the first and third pixels being disposed immediately adjacent to the left and right sides of the second pixel; a controller for applying, to the subpixels of the first or third pixel, data corresponding to a subpixel of a color not included in the second pixel. When the luminance level of the second pixel is lower than a first reference level and luminance difference between the first and second pixels or between the second and third pixels is greater than a second reference level, the controller may not apply the data to subpixels of the first or third pixel. Thus, on the RGBW type panel, sharpness of the edge area can be improved.

Tools and techniques are described to render oversize glyphs in a monospace grid. Glyph rendering algorithms collect changed cells, collect affected cells based on overlap, clear certain affected cells, and redraw only specified cells. By reducing the number of cells whose glyphs are redrawn in response a text edit, algorithms permit faster execution even when rendering is done by a script rather than precompiled code. Algorithmic advances also permit faster display frame rates, and help preserve battery power. Grids may be numbered, and traversed, in different ways. Oversize glyphs may include underscores, ligatures, mathematical symbols, emojis, kanji, accented characters in various natural languages, and wide or tall text characters which extend beyond the display space of a single cell. Glyph rendering may provide user interface updates in browsers, shells, terminal emulators, and other programs.

Tools and techniques are described to render oversize glyphs in a monospace grid. Glyph rendering algorithms collect changed cells, collect affected cells based on overlap, clear certain affected cells, and redraw only specified cells. By reducing the number of cells whose glyphs are redrawn in response a text edit, algorithms permit faster execution even when rendering is done by a script rather than precompiled code. Algorithmic advances also permit faster display frame rates, and help preserve battery power. Grids may be numbered, and traversed, in different ways. Oversize glyphs may include underscores, ligatures, mathematical symbols, emojis, kanji, accented characters in various natural languages, and wide or tall text characters which extend beyond the display space of a single cell. Glyph rendering may provide user interface updates in browsers, shells, terminal emulators, and other programs.