Abstract: Techniques for improving the performance of vector-based, fluid motion simulation techniques in procedural painting algorithms. The techniques may be implemented in procedural painting algorithms that employ a vector-based, fluid motion simulation technique to help achieve dynamic and serendipitous behaviors of watercolor painting at good interactive rates even on relatively low-powered devices. The techniques may include resampling the vertices of pigment polygons after growth at least at some iterations of the algorithm to provide smoother, more uniform growth; rasterizing dried pigment polygons into a texture so that the dried polygons are not rendered at each iteration of the algorithm; and rendering only a subset of live pigment polygons at each iteration of the algorithm. Polygons used by the techniques may be separated into static water polygons and dynamic pigment polygons.

Abstract: This patent relates to thin plate spline (TPS)-based interpolation techniques for representing free-flowing vector graphics (VG) images based on user-specified features, such as points and curves. One or more features can be identified in a pixel grid. A higher-order least squares interpolating function with a TPS smoothness objective can then be utilized to interpolate individual color values to individual pixels of the pixel grid. Smoothness terms of the function that impose smoothness penalties can be interrupted in certain regions of the pixel grid based on attributes of the user-specified features. For example, a curve attribute can specify a particular color value(s), add or remove a smoothness penalty, or anisotropically impose a first derivative constraint in a particular direction.

Abstract: Certain implementations of the disclosed technology may include systems and methods for changing a contrast level associated with an output for presentation on a display in response to detecting a change in a brightness level. According to an example implementation, a method is provided. The method includes determining, by a computing device, a first brightness level associated with an output for presentation on a display. The method also includes determining, by the computing device, a first contrast level associated with the output for presentation on the display. Responsive to detecting, by the computing device, a change from the first brightness level to a second brightness level, the method includes changing, by the computing device, the first contrast level to a second contrast level.

Abstract: Image processing apparatus comprises a memory unit configured to store medical data, and a data processing unit configured to receive medical data from the memory unit and comprising an image generation unit configured to generate a medical display image, the medical display image comprising a background region image and a foreground image derived from the medical data, wherein a brightness of the background image changes in a region between a boundary of the background region and a periphery of the medical display image.

Abstract: Areas of a video signal that represent light emission are detected, the luminance levels at which said light emission areas are displayed are enhanced, emphasizing said areas, and said luminance stretching is controlled in accordance with a set image quality mode, thereby producing consistently natural, high-quality visual imagery. A light emission detecting portion (12) counts pixels in order to generate a histogram of a prescribed feature quantity of an input video signal and identifies areas that fall within a prescribed range at the upper end of said histogram as being light emission areas. On the basis of a brightness-related index computed from the input video signal on the basis of prescribed conditions, an area-active-control/luminance-stretching portion (14) performs luminance stretching, increasing the luminance of a backlight portion (16) and reducing the luminance of non-light emission areas of the video signal, i.e. the areas other than the light emitting areas.

Abstract: A method for colorization of images is presented. The method comprises the following steps: Displaying an image (102); applying multiple color markings (at least two colors are different) to the displayed image (104); automatically coloring the image by applying a constrained optimization to a cost function that is responsive to the marked colors and the intensity differences of the neighborhoods of some of all of the pixels (106); the resultant image is subsequently stored (110), displayed (108), or transferred (112).

Abstract: Embodiments of the present invention comprise systems, methods and devices for increasing the perceived brightness of an image. In some embodiments this increase compensates for a decrease in display light source illumination.

Abstract: An adder adds, to a luminance value indicated by the image signal of the nth frame, a correction value corresponding to a combination of a luminance value indicated by the image signal of the nth frame and one indicated by the image signal of the (n+1)th frame. The adder outputs an image signal having the luminance value after addition as the image signal of the nth frame.

Abstract: A system for displaying video on electronic paper displays to reduce video playback artifacts comprises an electronic paper display, a video display driver, a video transcoder, a display controller, a memory buffer and a waveforms module. The video display driver receives a re-formatted video stream, which has been processed by the video transcoder, from the memory buffer. The video display driver directs the video transcoder to process the video stream and generate pixel data. The video display driver loads waveforms into the frame buffer and updates display commands repeatedly to activate the display controller until the end of the video playback. The video display driver directs copying video frames sequentially one by one from the memory buffer to the frame buffer in real time during the video playback. The video transcoder receives a video stream for presentation on the electronic paper display and processes the video stream generating pixel data that is provided to the display controller.

Abstract: Graphics processing may include implementing a vertex shader and a pixel shader with the GPU. Vertex indices output from a vertex shader may be written to a cache. The vertex indices written to the cache may be accessed with the pixel shader and vertex parameter values associated with the vertex indices may be accessed from a memory unit with the pixel shader. It is emphasized that this abstract is provided to comply with the rules requiring an abstract that will allow a searcher or other reader to quickly ascertain the subject matter of the technical disclosure. It is submitted with the understanding that it will not be used to interpret or limit the scope or meaning of the claims.

Abstract: This invention can develop a part of RAW image data and display the developed part of RAW image data with a result of processing, even if the part of the RAW image data refers to other part of the RAW image data. An image processing apparatus obtains an output area of RAW image data to be displayed on a window and a reference area of RAW image data to be pasted to the output area of the RAW image data. The apparatus develops the output area of the RAW image data and the reference area of the RAW image data. Then, the apparatus pastes a development result of the reference area of the RAW image data on a development result of the output area of the RAW image data. After that, the apparatus executes display processing to the development result of the output area of the RAW image data.

Abstract: A graphics processing may include implementing a vertex shader and a pixel shader with a GPU. Vertex parameter values may be compressed with the vertex shader and compressed vertex parameter values may be written to a cache. The pixel shader may access the compressed vertex parameter values that were written to the cache and decompress the compressed vertex parameter values. It is emphasized that this abstract is provided to comply with the rules requiring an abstract that will allow a searcher or other reader to quickly ascertain the subject matter of the technical disclosure. It is submitted with the understanding that it will not be used to interpret or limit the scope or meaning of the claims.

Abstract: A device that provides a map and/or navigation application that displays items on the map and/or navigation instructions differently in different modes. The applications of some embodiments provide a day mode and a night mode. In some embodiments the application uses the day mode as a default and activates the night mode when the time is after sunset at the location of the device. Some embodiments activate night mode when multiple conditions are satisfied (for example, when (1) the time is after sunset at the location of the device and (2) the ambient light level is below a threshold brightness).

Abstract: A GPU is configured to read and process data produced by a compute shader via the one or more ring buffers and pass the resulting processed data to a vertex shader as input. The GPU is further configured to allow the compute shader and vertex shader to write through a cache. Each ring buffer is configured to synchronize the compute shader and the vertex shader to prevent processed data generated by the compute shader that is written to a particular ring buffer from being overwritten before the data is accessed by the vertex shader. It is emphasized that this abstract is provided to comply with the rules requiring an abstract that will allow a searcher or other reader to quickly ascertain the subject matter of the technical disclosure. It is submitted with the understanding that it will not be used to interpret or limit the scope or meaning of the claims.

Abstract: A method, system, and computer-readable storage medium are disclosed for rendering knockout groups using a graphics processing unit (GPU). Input comprising at least one knockout group may be received at the GPU. The knockout group may comprise a plurality of objects that are ordered by paint order. Each object may be represented in the input by a plurality of vertices. The plurality of objects may be drawn into a frame buffer of the GPU such that a topmost object at each pixel in the frame buffer determines a color and an opacity of the pixel with respect to the other objects in the knockout group. In drawing the plurality of objects of the knockout group into the frame buffer of the GPU, program code may be executed by the GPU.

Abstract: An image processing device including: a local mean image generating section; a binarization image generating section configured to generate a binarization image, wherein pixels corresponding to high frequency regions and low frequency regions have a first and second grey scales, respectively; a ternarization image generating section configured to divide, based on comparison between the image and the local mean image, first grey scale regions in the binarization image into regions having the first grey scale and regions having a third grey scale; a filling section configured to recognize connected regions having the second grey scale in the ternarization image, to fill the connected regions with the first grey scale or with the third grey scale according to grey scale of pixels at boundaries of the connected regions; and a recognizing section configured to recognize strokes according to consistency of grey scale at object boundaries in the filled ternarization image.

Abstract: A global image adjustment, such as dynamic range adjustment is established based on image characteristics. The image adjustment is based more heavily on pixel values in image areas identified as being important by one or more saliency mapping algorithms. In one application to dynamic range adjustment, a saliency map is applied to create a weighed histogram and a transformation is determined from the weighted histogram. Artifacts typical of local adjustment schemes may be avoided.

Abstract: When a single pixel is displayed by four color sub-pixels, or R (red), G (green), B (blue), and G, in a Bayer array, this invention sets the scaling rate of a scaling process to 3/2 times when executing the scaling process on image data having three color components, or R, G, and B, and then executes a color conversion process for finding four color components from the three color components; after this, a decimation process for reducing the number of pixels is carried out. Setting the scaling rate of the scaling process to an integer proportion, moirés caused by the scaling process can be made less noticeable. Note that it is desirable for the scaling rate of the scaling process to be close to ?2 and for the denominator of the integer proportion to be lower.

Abstract: An image processor includes generates a content adaptive kernel from an image block with noise of a luminance component signal with a low resolution. The content adaptive kernel is convolved with the luminance component signal. A noise signal and an extracted texture which excludes noise are generated. The luminance component signal is filtered as function of the noise signal to generate an enhanced luminance component signal. Horizontal and vertical scaling is performed on the enhanced luminance component signal, the extracted texture, and the luminance component signal, with the luminance component signal adaptively scaled as a function of the extracted texture. The horizontally and vertically scaled enhanced luminance component signal, extracted texture and luminance component signal are then combined to generate an output luminance component signal with a high resolution.

Abstract: The disclosure provides for a dynamic skydome system for generating dynamic atmospheric and/or sky effects for use in electronic visual media, such as for games and movies. The features of the dynamic skydome system of the disclosure include mimicking real-world behavior of the sky through a 24 hour cycle, providing a physically based rendering model with multiple atmospheric scatterings; simulating astronomically correct celestial bodies; producing god rays; providing aerial perspectives; and dynamically lighting volumetric clouds.

Abstract: A rasteriser 10 of a graphics processing pipeline 1 tests larger patches of a render output to be generated against a primitive to be rasterised, to determine if the primitive covers (at least in part) any smaller patches of the render output that the larger patch encompasses. The larger patch is then sub-divided into any covered smaller patches, and the process repeated. The rasteriser 10 also identifies when a given smaller patch of the render output is found to entirely pass the edge test for an edge of the primitive in question when the larger patch encompassing that smaller patch is tested, notes that event in state information associated with the primitive edge in question, and then uses that state information to skip the testing of the edge in question against the smaller patch of the render output.

Abstract: Aspects of the invention are directed to method and system for simulating real-time processing of a virtual scene. The method includes acquiring a virtual scene; adding an effect to the virtual scene, and acquiring an effect scene; and invoking the effect scene so as to simulate real-time processing of the virtual scene. According to the invention, before the virtual scene is invoked, effect processing is performed on the virtual scene in advance according to effect requirements. When the virtual scene is invoked, an effect resulting from real-time processing of the virtual scene is simulated. Since there is no need for the computer where the computer game is played to perform processing in real time, the computer is not required to have very high performance capability to simulate real-time processing. Further, the virtual scene can be shown smoothly in a computer without very high performance configuration.

Abstract: In a tile-based graphics processing system, when a tile for a render output is to be generated, the fragment data storage requirements for each fragment to be generated for the tile is determined 51, and a colour and/or depth buffer in the tile buffer is allocated for use by the fragments for the tile based on the determination 57. The graphics processing pipeline then, when generating rendered fragment data for the tile, stores the rendered fragment data in the colour buffer and/or depth buffer of the tile buffer allocated to the fragments for the tile 58.

Abstract: An apparatus and method for providing a user interface are provided. The method includes determining a status of the mobile terminal, and rendering a user interface using one of the software mode and the hardware mode based on the status of the mobile terminal. Accordingly, because a hardware mode provides a high quality user interface but requires more power as compared to the software mode, the mobile terminal is able to reduce power consumption by automatically switching to the software mode based on the status of the mobile terminal.

Abstract: A method and an apparatus for brightness-controlling image conversion. The method includes converting an input image of a first non-linear color space into a second linear color space; determining a brightness control ratio; adjusting channels of the second linear color space according to the brightness control ratio; converting the second linear color space into the first non-linear color space to form an output image.

Abstract: A method is provided in one example and includes receiving a video input from a video source coupled to a display configured for rendering a user interface thereon; evaluating a plurality of pixels within the video input; and determining if a particular pixel within the pixels is associated with a color that matches a designated value associated with a chroma-key. If a match is found for the particular pixel, then the particular pixel is rendered as a clear image on the display, and if the match is not found, the particular pixel is darkened by a certain percentage.

Abstract: A device that may be used as a multi-color pixel is provided. The device has a first organic light emitting device, a second organic light emitting device, a third organic light emitting device, and a fourth organic light emitting device. The device may be a pixel of a display having four sub-pixels. The first device may emit red light, the second device may emit green light, the third device may emit light blue light and the fourth device may emit deep blue light. A method of displaying an image on such a display is also provided, where the image signal may be in a format designed for use with a three sub-pixel architecture, and the method involves conversion to a format usable with the four sub-pixel architecture.

Abstract: The present invention provides a mechanism that more appropriately evaluates an image defect caused by a specific process in an image forming apparatus. An image forming apparatus of this invention performs colorimetry of a patch image at a spatial resolution corresponding to the spatial frequency of color unevenness caused by a specific process included in an image forming process. A statistic value based on the n-th (n is an integer of 2 or more) order central moment of a specific color component of a colorimetric value obtained by performing colorimetry at the spatial resolution is compared with a reference value, thereby detecting that the color unevenness caused by the specific process has occurred in the patch image.

Abstract: Colorimetric values for generating a color separation table, which are obtained by measuring a plurality of color patches included in a color chart, are input, and measurement values corresponding to the input plural measurement values other than supervised input measurement values are estimated using supervised measurement values. Then, color differences between the estimated measurement values and the input plural measurement values other than the supervised measurement values are calculated. Based on the color differences, it is determined whether printing of the plurality of color patches or measurement of the plurality of color patches has been performed correctly.

Abstract: An image display apparatus which divides the 1-frame period of input image data into a plurality of periods and displays image data in the respective divided periods separates high frequency component data by using the input image data, and distributes the amplitude of the high frequency component data for the image data in the respective divided periods to make the amplitude of the separated high frequency component data fall within a difference between the gradation of the input image data, and 0 gradation or the maximum gradation of an image.

Abstract: Flood-fill techniques and architecture are disclosed. In accordance with one embodiment, the architecture comprises a hardware primitive with a software interface which collectively allow for both data-based and task-based parallelism in executing a flood-fill process. The hardware primitive is defined to do the flood-fill function and is scalable and may be implemented with a bitwise definition that can be tuned to meet power/performance targets, in some embodiments. In executing a flood-fill operation, and in accordance with an example embodiment, the software interface produces parallel threads and issues them to processing elements, such that each of the threads can run independently until done. Each processing element in turn accesses a flood-fill hardware primitive, each of which is configured to flood a seed inside an N×M image block. In some cases, processing element commands to the flood-fill hardware primitive(s) can be queued and acted upon pursuant to an arbitration scheme.

Abstract: A viewing window of a map surface is determined, at a certain zoom level corresponding to the magnification of the map surface. A first set of style parameters for applying to a feature of the map surface, where the feature is described in a vector format using several interconnected vertices, is determined. The first set of style parameters corresponds to a first zoom level of the viewing window, and the first zoom level corresponds to a first magnification. A second set of style parameters for the feature is also determined, where the second set of style parameters corresponds to a second zoom level of the viewing window, and where the second zoom level corresponds to a second magnification. A third set of style parameters for displaying the feature is determined by interpolating between the first set of style parameters and the second set of style parameters.

Abstract: In accordance with some embodiments, processing power is applied based on the user's detected level of interest. In one embodiment, the user's detected level of interest in particular regions within a frame may be determined using an eye gaze detector or eye tracking apparatus. Those frame regions or areas that the user spends more of his or her attention on may be processed faster, at higher resolution or otherwise to enhance their depiction.

Abstract: Computer input devices are described herein for use in manipulating digital images on a display apparatus.

Abstract: Illustrated is a system and method to use a photometer to receive a light vector, the photometer to determine intensity of the light vector. The system and method also uses a processor to determine a location of a light source that generates the tight vector. Additionally, the system and method uses a touch-sensitive screen to display an icon pixel shaded based upon the intensity of the light vector and the location of the light source.

Abstract: An apparatus is provided that includes a processor and memory storing executable instructions that in response to execution by the processor cause the apparatus to at least perform a number of operations. The apparatus is caused to receive a digital image including pixels each of which has a pixel value that has been calibrated according to a first calibration function for calibrating an image for display by a first monitor. The apparatus is caused to transform the pixel value of each of at least some of the pixels to a corresponding transformed pixel value calibrated according to a second calibration function for calibrating an image for display by a second monitor. The apparatus is also caused to cause output of the digital image including the plurality of pixels each of at least some of which has a transformed pixel value, the respective digital image being displayable by the second monitor.

Abstract: A liquid crystal display device and a method of driving the same are provided for one or more embodiments. The liquid crystal display device includes: a liquid crystal panel including a plurality of display blocks and displaying an image in response to image signals; a plurality of light-emitting blocks emitting light to the liquid crystal panel and corresponding to the plurality of display blocks; a first look-up table including a normalized value obtained by normalizing an initial duty ratio corresponding to the brightness of the image to a maximum duty ratio corresponding to the maximum brightness of the image; and a timing controller receiving the normalized value corresponding to each of the light-emitting blocks from the first look-up table and using the normalized value to provide an optical data signal corresponding to each of the light-emitting blocks.

Abstract: A method and a system for fusing images in an image processing field are described. The method includes: capturing at least two frames of images having different intensity under different exposure time in the same scene; fusing the images having different intensity values according to an intensity mapping relation between every two frames of images in the images having different intensity values, and obtaining a fused image is, in which the intensity mapping relation represents a corresponding relation between an intensity value of a pixel location in a bright image and that at the corresponding location in a dark image. Through the method and the system for fusing the images according to the present invention, the dynamic range of the image is enhanced, and the fusing process has a desired result and is easy to implement.

Abstract: The purpose of the present invention is to provide a display device in which the occurrence of crosstalk can be suppressed. A display device (10) includes a display unit and a separation unit (34). The display unit displays a synthetic image formed by dividing each of a plurality of images that are different from one another and arraying the divisional images thus obtained in a predetermined order. The separation unit (34) separates the plurality of images contained in the synthetic image. The display unit includes a storage unit (54) and a correction unit (52). The storage unit (54) stores crosstalk levels set with respect to respective combinations of gray scale level data including gray scale level data of a pixel displaying an image that a viewer is supposed to see, among the plurality of images contained in the synthetic image, and gray scale level data of a pixel serving as a factor that causes crosstalk.

Abstract: A system, method, and computer program product are provided for producing images for a near-eye light field display. A ray defined by a pixel of a microdisplay and an optical apparatus of a near-eye light field display device is identified and the ray is intersected with a two-dimensional virtual display plane to generate map coordinates corresponding to the pixel. A color for the pixel is computed based on the map coordinates. The optical apparatus of the near-eye light field display device may, for example, be a microlens of a microlens array positioned between a viewer and an emissive microdisplay or a pinlight of a pinlight array positioned behind a transmissive microdisplay relative to the viewer.

Abstract: A measurement apparatus comprises a light source of line shape configured to move in a predetermined direction and illuminate a measurement target object, and a capturing unit configured to capture the measurement target object illuminated by the light source of line shape. The measurement apparatus controls the light source of line shape and the capturing unit, and estimates the reflection characteristics of the measurement target object from a plurality of images captured by the capturing unit.

Abstract: A system, method, and computer program product are provided for producing images for a near-eye light field display. Defect information for a first pixel of a microdisplay of a near-eye light field display device is received and a second pixel of the microdisplay is identified, where the first pixel and the second pixel contribute to a portion of the retinal image. Based on the defect information, a value of the second pixel within an array of elemental images is modified to produce a corrected array of elemental images for display by the microdisplay. An optical apparatus of the near-eye light field display device may, for example, be a microlens of a microlens array positioned between a viewer and an emissive microdisplay or a pinlight of a pinlight array positioned behind a transmissive microdisplay relative to the viewer.

Abstract: To generate a description of a raster map image that includes a representation of a body of water having a color gradient that appears constant in response to a zoom operation, a description of geometry of the body of water is generated for a selected geographic area. Using a raster representation of the body of water having a color gradient, at least two blur raster images are generated: a first blur raster image is generated using a first blur radius, and a second blur raster image is generated using a second blur radius different from the first blur radius. The description of the geometry of the body of water, the first blur raster image, and the second blur raster image are provided to a client device for generating raster map images of the selected geographic area.

Abstract: According to one embodiment, an decoloring apparatus includes: an decoloring processing unit configured to apply decoloring processing decoloring a color of an decolorable colorant; a sheet conveying unit configured to convey the sheet and cause the sheet to pass through the decoloring processing unit; an image reading unit arranged further on an upstream side than the decoloring processing unit in a sheet conveying direction by the sheet conveying unit and configured to read the image formed on the sheet conveyed by the sheet conveying unit; a thickness sensor arranged further on the upstream side than the decoloring processing unit in the sheet conveying direction by the sheet conveying unit and configured to detect thickness of the sheet conveyed by the sheet conveying unit; an decolorability determining unit configured to determine, on the basis of a detection result in at least one of the image reading unit and the thickness sensor, executability of the decoloring processing in the decoloring processing

Abstract: Provided is an image processing device. A first color space converting unit converts image data in an RGB colorimetric system, which has a color gamut wider than a color gamut of a liquid crystal panel into image data in an XYZ colorimetric system. A three-dimensional nonlinear color gamut converting unit performs conversion on tristimulus values of the XYZ signal. At this time, the image data is classified into four colors and converted respectively such that the first color is displayed in a color accurate to the inputted data, the second color is displayed such that saturation of the second color is increased, the third color is displayed using a color gamut of a predetermined range out of the color gamut of the liquid crystal panel, and the fourth color is displayed in a color corresponding to a boundary of the color gamut of the liquid crystal panel.

Abstract: Provided are a computer system and methods related to a map display. A method includes but is not limited to receiving a request for the map, the map illustrating one or more locations; determining a status associated with at least one of the one or more locations on the map, the status being a function of one or more location interaction rules associated with the at least one of the one or more locations on the map; and generating a signal related to indicating on the map the status associated with the at least one of the one or more locations.

Abstract: An emulator yields modified image data that predicts the appearance of image content on a target display. The emulator generates modified image data based in part on the image content. The emulator may perform a transformation in which one or more parameters representative of features such as black level and/or white level of the target display are functions of image statistics for the image content.

Abstract: A method and system according to the disclosure facilitates subscription based access to services for image systems including an image acquisition device configured to generate image data describing a target object in a target area of the image acquisition device and an image display device configured to generate a human perceptible rendering of the target object based on the image data.

Abstract: An interactive data object map system is disclosed in which large amounts of geographical, geospatial, and other types of data, geodata, objects, features, and/or metadata are efficiently presented to a user on a map interface. The interactive data object map system allows for rapid and deep analysis of various objects, features, and/or metadata by the user. A layer ontology may be displayed to the user. In various embodiments, when the user rolls a selection cursor over an object/feature an outline of the object/feature is displayed. Selection of an object/feature may cause display of metadata associated with that object/feature. The interactive data object map system may automatically generate feature/object lists and/or histograms based on selections made by the user. The user may perform geosearches, generate heatmaps, and/or perform keyword searches, among other actions.

Abstract: A display mode adjusting method and a display mode adjusting module executing the adjusting method are provided. The method includes the following steps: generating a saturation adjusting output color according to an input color to adjust the saturation; obtaining a relative color temperature adjusting parameter according to a target color temperature and an original optical characteristic of a display device; generating a color temperature adjusting output color according to the saturation adjusting output color and the relative color temperature adjusting parameter to adjust the color temperature; obtaining a brightness adjustment value according to the brightness of ambient light to adjust the brightness. Therefore, the display mode of the display device is adjusted to suitable for reading, which avoids the eyestrain when the users read for a long time.