Abstract: A method for a device to enlarge a displayed font, includes: receiving an instruction for enlarging a currently displayed font; acquiring a size of the currently displayed font; when the size of the currently displayed font is smaller than a preset maximum threshold, enlarging the currently displayed font based on a curve enlargement rule with a first enlargement coefficient configured by an operating system of the device and a second enlargement coefficient configured by a current application; when the size of the currently displayed font is larger than or equal to the preset maximum threshold, enlarging the currently displayed font based on a linear enlargement rule with a third enlargement coefficient configured by the operating system; and displaying the enlarged font.

Abstract: An image processing method for processing an input image is provided. The image processing method includes: performing a plurality of first imaging processing operations on the input image to generate a first image; and performing a plurality of second imaging processing operations on the first image. Each of the first imaging processing operations is along a first direction, and the plurality of first imaging processing operations include a first scaling operation for increasing resolution. Each of the second imaging processing operations is along a second direction different from the first direction, and the plurality of second imaging processing operations include a second scaling operation for increasing resolution.

Abstract: An image processing circuit and a method thereof are provided herein. The image processing circuit has a first scaling circuit, one or more line buffers, a first sharpness circuit, a second scaling circuit, and a second sharpness circuit. The first scaling circuit enlarges an input image along a first direction to generate a first enlarged image. The one or more line buffers temporarily store the pixel values of a plurality of pixel rows of the first enlarged image. The first sharpness circuit vertically sharpens the first enlarged image to generate a first sharpened image. The second scaling circuit enlarges the first sharpened image along a second direction to generate a second enlarged image. The second sharpness circuit horizontally sharpens the second enlarged image to generate a second sharpened image. Accordingly, it is possible to use the one or more line buffers having shorter data lengths to perform the vertical sharpening.

Abstract: When a display position for any of a plurality of images is designated using a touch panel, an instruction accepting section enlarges, for a predetermined period of time, an area for accepting the input of an instruction associated with any of the image of the plurality of images that is displayed in the designated display position, in accordance with speed of change that is detected by a speed detector at the time of the designation.

Abstract: Systems and methods are provided for displaying and manipulating the display of digital character strings where the length of the character string extends beyond the width of a desired output display. In response to a user request to display a character string, a client can generate a truncated representation of the character string using at least one truncation symbol when the character string extends beyond the width of an output display. A client can modify the display of the truncated representation of the character string in response to detecting a signal. For example, the client can display a selected character string in its entirety or an excerpt of the truncated representation. The signal can be detected from a touchscreen or input device. This allows a user to view those portions of the selected character string that may be obscured by the truncation symbol.

Abstract: A computerized font size adjustment method of an electronic device, the electronic device includes an image capturing device. Images of a user are captured using the image capturing device at intervals. A smallest rectangle framing an eye portion of a current image of the user and a ratio of a length to a width of the smallest rectangle are calculated. Then the ratio is compared with a predetermined value range, and the font size of the electronic device is adjusted according to the comparison.

Abstract: An image processing circuit and a method thereof are provided herein. The image processing circuit has a first scaling circuit, a plurality of line buffers, a first sharpness circuit, a second scaling circuit, and a second sharpness circuit. The first scaling circuit enlarges an input image along a first direction to generate a first enlarged image. The line buffers temporarily store the pixel values of a plurality of pixel rows of the first enlarged image. The first sharpness circuit vertically sharpens the first enlarged image to generate a first sharpened image. The second scaling circuit enlarges the first sharpened image along a second direction to generate a second enlarged image. The second sharpness circuit horizontally sharpens the second enlarged image to generate a second sharpened image. Accordingly, it is possible to use the line buffers having shorter data lengths to perform the vertical sharpening.

Abstract: An image processing apparatus includes a storage that stores, therein, edge position data indicating the position of a first edge image that represents a first edge of a first object image representing an object in a first image, a determination portion that detects a second edge image based on the edge position data and a specific scaling factor, the second edge image representing a second edge of a second object image that represents the object in a second image, the second image being obtained by modifying the size or the resolution of the first image by increasing the number of pixels by ? times (?>1) corresponding to the scaling factor, the second edge having a width equal to that of the first edge, and a removal portion that performs a process for deleting an edge of an inner area surrounded by the second edge image.

Abstract: Disclosed is a system and method for converting a digital number to text and for pronouncing the digital number. The system includes a filtration system for determining whether the digital number has nonnumeric symbols and for generating a filtrated number, an analyzing system for analyzing the filtrated number, a composition system configured to collect words associated with ternary units of the filtrated number, a linking system configured to link the words, and a pronouncing system for pronouncing the linked words.

Abstract: Methods, systems, and apparatus, including computer programs encoded on a computer storage medium, for modifying glyphs. In one aspect, a method includes receiving a glyph outline for a glyph to be rendered, the glyph to be rendered being associated with a character of a particular font and at a specified scaled size, the glyph to be rendered having one or more horizontal stems; identifying a darkening amount to be applied to the one or more horizontal stems of the glyph; modifying hints of the one or more horizontal stems of the glyph outline using the identified darkening amount to modify the glyph outline; and rasterizing the glyph using the modified glyph outline.

Abstract: Imposition system and drivers for printer products prepare a document for printing by receiving an electronic document to be printed, determining a smallest font size of the text of at least a portion of the document; determining a scale factor for at least one portion of the document based on the smallest font size and a predetermined minimum font size; and scaling at least a portion of the document by the scale factor.

Abstract: A computer readable recording medium storing a printer driver causing a computer to execute a process for generating, based on printing target data, printing data and sending to a printing device, the process which includes: selecting a character with a specific typeface from the printing target data; performing conversion of the selected character with the specific typeface into a character with other typeface; and generating the printing data based on the printing target data including the converted character.

Abstract: An image rendering processing device includes an expanding section, a signal output section, and a writing section. The expanding section reads out font data corresponding to the character code indicated in image rendering data and expands the font data into a size corresponding to horizontal and vertical pixel numbers of the image rendering data. The signal output section (a) reads out a valid range corresponding to the character code, (b) adjusts the valid range based on the pixels of the expanded font data, and counts the pixels in the expanded font data along the specific direction, and (c) outputs a valid signal indicating that a given pixel corresponds to the valid range when a counted pixel number matches the pixel number of a pixel corresponding to the valid range. The writing section writes the pixel that corresponds to the pixel number which is counted when the valid signal is output.

Abstract: Methods and apparatus, including computer program products, that implement a method for glyph adjustment in high resolution raster while rendering. In one aspect, a method includes the actions of receiving a glyph for display at a size on a raster output device; receiving a grid ratio specifying an integer number of fine pixels of a high resolution grid that correspond to a device pixel of the output device; rendering the glyph at the size on the high resolution grid; determining for each line of pixels of the high resolution grid, a line-specific, per-transition adjustment number; and in each line of pixels, marking or erasing the line-specific, per-transition adjustment number of fine pixels in the high resolution grid at each transition from a marked fine pixel to an unmarked fine pixel in a particular direction of the line of pixels.

Abstract: Methods and apparatus, including computer program products, implementing and using techniques for rendering a glyph to make it more readable. In an implementation, a glyph associated with a font to be rendered at a size is received, and a set of initial density values is calculated to provide one density value for each of a set of device pixels to represent the glyph. An initial adjustment value is calculated for the glyph. For one or more of the device pixels in the set of device pixels, a length of an edge of the glyph that passes through the device pixel is calculated. For one or more of the device pixels, the initial density value is adjusted by a final adjustment value, the final adjustment value based upon the initial adjustment value and the length of the edge of the glyph passing through the device pixel.

Abstract: A graphic character that has a character matrix with a number of character units that are indivisible at least in either a horizontal direction or a vertical direction is scaled by dividing the character matrix into one first and at least one second character segment, each comprising at least one of the character units. The first character segment is symmetrically scaled using a first scaling factor and the second character segment is scaled using a second scaling factor different from the first scaling factor.

Abstract: In a portable telephone, a sensor constructed of, for example, a 3-axial acceleration sensor is built in the vicinity of a display unit which is provided on a main body of the portable telephone. When a user moves the display unit along a vertical direction (Z-axis direction) with respect to a display screen thereof while the user holds the appliance main body, the sensor senses both a move direction and a move amount of the display unit, and thus, information displayed on the display screen of the display unit is enlarged, or compressed in display magnification defined in response to the sensed move amount. As a result, a display size of the information displayed on the display screen can be changed in such a manner that the user may have such a natural feeling achieved by moving a magnifying glass.

Abstract: A character within a font is enlarged to a desired size by first determining whether the font contains existing or predefined variants of the character having the desired size. If no appropriately sized variant exists, the enlarged character is assembled from a plurality of component glyphs that are stored with the font, wherein the component glyphs include an extender that may be duplicated within the assembled character in order to achieve the desired size. In one embodiment, the font includes tables containing records of the enlarged variants for a particular character, as well as part records for the component glyphs used to assemble the enlarged character.

Abstract: The system, method and program of the invention enables a presentation authoring tool, that is used to create presentation data for later projection, to determine a recommended font size for the created presentation data displayed on a display screen of a computer executing the presentation authoring tool. The user interface presents a display screen for receiving input of an expected viewing distance for the later projection of the presentation. The recommended font is determined based upon the expected viewing distance of the later projection having a projected font size viewable by a person, having a certain vision capability, at the expected viewing distance. The expected viewing distance may be a maximum viewing distance or a room depth of a room in which the later projection takes place.

Abstract: Methods and apparatus implementing and using techniques for rendering a stroke (e.g., a line or glyph). An initial adjustment value can be calculated for the stroke, and an offset amount calculated based on the initial adjustment value, such that a minimum number of device pixels will be marked by the stroke after adjusting density values of device pixels representing the stroke. A high resolution representation of the stroke (e.g., a set of device pixels each having an initial density value) is rendered so that one or more edges of the stroke is offset from a device resolution grid by the offset amount. A length of an edge of the stroke that passes through a device pixel can be calculated, and the density value of the device pixel adjusted by a final adjustment value based on the initial adjustment value and the length of the edge of the stroke.

Abstract: A text enhancement unit is introduced in order to alleviate the degradation of text characters on computer or television displays. The text enhancement unit uses an enhancement process to regain uniformity and intensity that may be lost during image processing. The text enhancer unit may be placed between an image processing unit such as a scaler, de-interlacer, or DSP, and a computer or television display to improve the quality of text characters that may have become degraded by image processing performed by the image processing unit. In one embodiment, the text enhancer unit improves contrast by multiplying pixel intensity by an intensity multiplier. In a second embodiment, the text enhancer unit improves contrast using a threshold operation which outputs either a very high or very low intensity pixel. In an third embodiment, the text enhancer unit improves contrast using a threshold operation which outputs either a very low intensity pixel or a pixel multiplied by an intensity multiplier.

Abstract: A method and apparatus for horizontally expanding a video graphics adapter (VGA) text character display image to fully fill the screen of a flat panel display. Cell lines for each character are remapped to provide expanded cell lines. The flat panel apparatus includes a video memory for storing the character code, attribute data and font data, a character generator for generating character font data based on the character code, a lookup table for providing expanded cell lines, and an attribute controller for combining the font data and the attribute data for output to a flat panel display.

Abstract: To allow for switching between a normal display and a zoom display by a simple operation, thereby providing both of a large amount of information by high resolution and high visibility of the display. In a computer system having a display apparatus as output unit, an input section 50 for accepting a user operation to issue a request for changing a display zoom factor, a resolution changer 10 for changing the resolution of the display apparatus in response to the request for changing the display zoom factor issued by the input section 50, and a window resizer 20 for resizing a predetermined window displayed on the display screen 70 of the display apparatus so as to be displayed over almost the entire display screen 70 after the resolution is change by the resolution changer 10.

Abstract: A character within a font is enlarged to a desired size by first determining whether the font contains existing or predefined variants of the character having the desired size. If no appropriately sized variant exists, the enlarged character is assembled from a plurality of component glyphs that are stored with the font, wherein the component glyphs include an extender that may be duplicated within the assembled character in order to achieve the desired size. In one embodiment, the font includes tables containing records of the enlarged variants for a particular character, as well as part records for the component glyphs used to assemble the enlarged character.

Abstract: A method of rendering a glyph of a vector-based font comprises the steps of: generating a MIP map for a glyph, where the MIP map comprises at least one level having a plurality of pixels and where each level is generated from original vector data for the glyph; and storing the MIP map on a computer readable medium. The method further comprises placing the glyph in an image to be rendered; retrieving the stored MIP map for the glyph; rendering a level of the MIP map, where the level is associated with a resolution of the glyph; and displaying the glyph as the rendered level.

Abstract: According to one embodiment, a handheld device is disclosed. The handheld device includes a housing, a display mounted within the housing, and a font magnification mechanism. The font magnification mechanism automatically magnifies a font being displayed on the display to a larger font whenever the handheld device is operating in dim lighting conditions.

Abstract: Vector quantization provides font contour data reduction. Characters are defined in a font collection using segmented outline forms and common references stored to curve segments for similar segments in different characters of the font collection. Compressing the font collection preferably includes applying an entropy encoding data reduction. The common references are stored in a segment storage location. Another aspect includes decompressing a font store containing a compressed collection of outline fonts. The uncompressed curve segments are scaled so as to match a requested size for a letterform.

Abstract: The invention provides a font processing device. In font enlargement, a target font to be enlarged or reduced is divided into columns or rows, and a cost is calculated based on the pixel pattern formation for each column and row. In enlargement processing, a cost represents a line segment volume, and a column or a row that has low-cost, that is, has a pixel array close to a line segment, is difficult to be enlarged. Further, in reduction processing, a cost represents a degree of likeness to an adjacent column or row, and a column or a row that has a similar pixel pattern is reduced with priority. In practice, the column or row for the target font is decided based on the pixel formation of the target font for enlargement or reduction so that natural enlargement/reduction can be obtained. In addition, font modification is executed by using enlargement and reduction of the font.

Abstract: A menu display apparatus including a selection unit for inputting data for selecting an arbitrary one of a plurality of menu items respectively assigned with numbers which are displayed on a screen of a display unit, and a display control unit for displaying on the screen the number corresponding to the menu item selected by the selection unit.

Abstract: Character data to be displayed is obtained. The obtained character data is boldfaced by increasing a character line width of the obtained character data in a first direction by an amount corresponding to at least a width of a light-emitting element. A boldfaced character is displayed on a display screen in accordance with data derived from the boldfaced character data. In boldfacing the character data, a character line width-increasing pattern is selected in accordance with a degree to which the luminous intensity of the light-emitting elements contributes. In particular, the step of increasing the character line width in order to boldface the character data avoids a pattern in which a B-light (blue) emitting element is located at a next-to-endmost inner position of the increased character line width. A light-emitting pattern is selected in order to eliminate an isolated sub-pixel spot, which otherwise would objectionably be visible in the boldfaced character.

Abstract: A system and method are disclosed that enable robust resizing of a simple polygon in a computationally inexpensive manner. A preferred embodiment is operable to handle various resizing events that may be encountered when resizing a simple polygon, such as self-intersection, edge-collapse, and edge-split events, in order to accurately generate the correct resized polygon. Further, a preferred embodiment is operable to compute a resulting resized polygon with efficiency of O(n log n), even if one or more of the above types of events is encountered during the resizing process. Embodiments of the present invention handle resizing events for simple polygons (both convex and non-convex) without requiring construction of the straight skeleton of the polygons being resized. Also, embodiments of the present invention are operable for resizing simple polygons that may include holes.

Abstract: A font controlling method and apparatus in a so-called on-screen display (OSD), in which, when displaying letters or the like of different languages, well-balanced high-quality display that is easy and comfortable to see is enabled without abbreviating a word or splitting one line into two lines. To this end, the font controlling apparatus includes an input signal discriminating unit 2, an OSD control micro-computer 3 and a character generator IC 5. The input signal discriminating unit 2 discriminates the sort of graphics display standard of an input signal. OSD control micro-computer 3 determines the sort of the font in use and size of the font based on a display language request signal from the user and the sort of graphics display standard of the input signal. The character generator IC 5 generates an OSD display signal responsive to the sort of the font determined by OSD control micro-computer 3 and the font size.

Abstract: A method and apparatus for horizontally expanding a video graphics adapter (VGA) text character display image to fully fill the screen of a flat panel display. Cell lines for each character are remapped to provide expanded cell lines. The flat panel apparatus includes a video memory for storing the character code, attribute data and font data, a character generator for generating character font data based on the character code, a lookup table for providing expanded cell lines, and an attribute controller for combining the font data and the attribute data for output to a flat panel display.

Abstract: A method and system for creating a controllable, shaped, and scalable graphical user interface (“GUI”) object for use in an application program displayed on a computer. An infinite resolution scheme according to the present invention may display a GUI in any shape at any size with minimal or no loss of original image quality. Infinite resolution may be accomplished by storing optimized vector image data (“OVID”), as opposed to raster-type data, for the outline and body of the image to be displayed. When the image is resized or reshaped, the OVID is accessed so that the original quality of the image is captured and maintained.

Abstract: An image processor is composed of a game device body, an operation panel and a display. The game device body is composed of a data processor 12 and a memory 12. The data processor realizes a hit determining circuit 112, an enemy control circuit 112, an enemy (object) set circuit 114, a cursor control circuit 114, an enemy retrieval circuit 116 and a camera control circuit 116 in accordance with corresponding programs used. When an object is displayed on the display, the cursor control circuit displays a cursor in accordance with predetermined processing performed on the basis of data on the coordinates of the object. The camera control circuit 116 performs a zoom-in display process for the object when the object is displayed on the display.

Abstract: A display control apparatus controls attributes of characters to be displayed on a display unit. The display control apparatus includes a storage storing predetermined attributes, and a converter for converting attributes of each of characters making up an input character string by referring to the storage so that characters making up a converted character string have the predetermined attribute. The converted character string is output for display on the display unit.

Abstract: A computer system, display device, display controller, and image processing method are described which provide high visibility and usability. A portion of an image displayed on a display screen of the display device is enlarged in one direction and the enlarged image is displayed in a window. In one example, a portion of the image displayed in the display is enlarged in the vertical direction when the text runs along a horizontal direction.

Abstract: A method of displaying a zoomed version of stored image on a display, where the stored image is defined by a set of data entries mapped to respective pixels of the display. The stored image is first scaled relative to the display in accordance with the desired zooming ratio. The scaled image is then located at an initial position relative to the display and the extent to which each display pixel is overlapped by features of the scaled image is determined. A color tone is assigned to each display pixel in accordance with the extent of the overlap. The scaled image is then shifted relative to said initial position one or more times and, for the or each shift, the overlap of each display pixel is recalculated and a new color tone assigned. The sets of assigned color tones are then displayed cyclically on the display to produce a displayed image.

Abstract: Apparatus comprising a logic member and a shear member incorporating an upsampler are used to enlarge the number of pixels in at least one image dimension by a factor F=N/M, where N is a first given-valued integer, M is a second given-valued integer and 1<N/M≦2. The shear member shears the original image at certain positions of the one dimension that are determined solely by the value of factor F, thereby introducing zero-valued shear-gap pixels at each of the certain positions.

Abstract: Image data processing and image rendering methods and systems whereby images are displayed on display devices having pixels with separately controllable pixel sub-components. Images, such as text characters, are displayed on a display device with at least some features being rendered with sub-pixel precision. The displayed advance width of a character displayed with sub-pixel precision is compatible with the advance width of the character if it had instead been displayed with a conventional full pixel precision rendering process. Thus, characters are displayed with sub-pixel precision, resulting in improved resolution and readability, while the advance width and the corresponding size and spacing of the characters and the overall formatting of the document remains the same compared to documents and characters rendered using conventional full pixel precision processes.