Abstract: Techniques for visual representation of chart scaling are described. In implementations, a chart is employed to display data associated with a resource. Examples of such a resource include a computer hardware resource, a network resource, a financial resource, a commodity (e.g., a manufactured commodity), and so on. In implementations, a chart is associated with a scale that corresponds to a set of data values represented in the chart. Further, a chart can be rescaled to display data values in a variety of different scales, e.g., that correspond to different sets of data values. In at least some embodiments, a scale mark is provided which provides a visual indication of a scale represented in a chart. When the chart is rescaled, the scale mark is repositioned to indicate a change in scale. Thus, a scale mark can be dynamically repositioned to visually indicate different chart scales.

Abstract: A method and system for culling a patch of surface data from one or more tiles in a tile based computer graphics system. A rendering space is divided into a plurality of tiles and a patch of surface data read. Then, at least a portion of the patch is analyzed to determine data representing a bounding depth value evaluated over at least one tile. This may comprise tessellating the patch of surface data to derive a plurality of tessellated primitives and analyzing at least some of the tessellated primitives. For each tile within which the patch is located, the data representing the bounding depth value is then used to determine whether the patch is hidden in the tile, and at least a portion of the patch is rendered, if the patch is determined not to be hidden in at least one tile.

Abstract: A method and system render rasterized data by receiving non-rasterized page description language data and a corresponding transformation matrix representing transformation operations to be performed. The non-rasterized page description language data is rasterizing to create rasterized data. The corresponding transformation matrix is decomposed into a plurality of individual transformation operation matrices and a discrete transformation operation value, from a corresponding individual transformation operation matrix, is generated for each transformation operation to be performed upon the rasterized data. The transformation operations are performed upon the rasterized data based upon the generated discrete transformation operation values.

Abstract: In a method for displaying at least one property of an optically determined surface geometry of at least one three-dimensional object, in particular a tooth, on a display, in particular a computer screen, a defined region of the surface geometry is monitored to ascertain whether a defined criterion has been fulfilled. An amount of optically determined data of the defined region is a criterion. A number of defined regions of the surface geometry are assigned a property when all the regions of the number meet the criterion. The property is displayed graphically in a defined manner, wherein different properties are graphically displayed in a differing manner.

Abstract: An information processing device includes: a control section that displays, in response to an operation of an operation section, a piece of map information on a display section and acquires, in accordance with the piece of map information displayed on the display section, a list of content related to the piece of map information.

Abstract: A method and system may include a hardware texture unit having logic to receive parameters of a view ray for a pixel of a graphical scene, and determine an illumination of the view ray. The illumination, which could indicate an in-scatter illumination percentage for the view ray, may be passed to a software module such as a pixel shader for rendering of the pixel.

Abstract: An image display device comprises a first control part, a first storage, and a display part. The first storage holds rendering elements, each of which includes a combination of rendering target information and rendering setting information, and a priority order assigned to each rendering element. The rendering target information includes data identification information which designates three-dimensional data of a rendering target and mask information which designates a rendering target area. The rendering setting information includes information which designates a two-dimensional image rendering method and rendering parameter. The first control part determines, based on the rendering setting information and the mask information, whether executing priority processing is necessary.

Abstract: Spatial relationships are conveyed in multi-planar reconstruction (MPR). A 3D MPR display indicates relative position of MPR imaging planes to each other and/or anatomy at a given time. To better assist user understanding of the location of the MPR planes relative to each other and/or anatomy in transitioning to different relative locations, the transition is animated. The shift in planar position occurs gradually in the 3D MPR display despite user indication of a jump to another arrangement.

Abstract: Diversification of a game field is realized while maintaining appropriate visibilities of the game field and a player object. An information processing apparatus includes: an object control section which controls movement of the virtual object by performing, based on a predetermined condition, switching between a first and a second state in which a virtual object movable region in the virtual space is restricted to a first and a second region, respectively; an image generation section which generates an image taken by a virtual camera; and a virtual camera control section which sets, in the first state, the position of the virtual camera to a first viewpoint that is a high-angle viewpoint with respect to the first region, and sets, in the second state, the position of the virtual camera to a second viewpoint that is a viewpoint other than the high-angle viewpoint.

Abstract: Techniques for an input object for routing input for visual elements are described. In at least some embodiments, a region of a display area includes multiple graphic elements that can be generated and/or managed by different graphics functionalities. For instance, a graphical user interface (GUI) for an application can include a primary window and visual elements within the primary window, such as banners, control buttons, menus, Tillable fields, and so forth. In at least some embodiments, the primary window of the GUI can be managed by a first graphics functionality, while one or more visual elements within the primary window can be managed by a second graphics functionality. In accordance with one or more embodiments, an input object is employed to route input to visual elements to a graphics functionality responsible for managing the visual elements.

Abstract: For each layer, a scaling rate of an object image or a background image belonging to each of the layers is calculated based on a distance from a predetermined reference point in a virtual three-dimensional space to each of the layers. In addition, for each of the layers, a movement velocity of each of the layers when conducting a parallax scrolling is calculated based on a distance from the predetermined reference point in the virtual three-dimensional space to each of the layers. Furthermore, an image in each of the layers is scaled up or down based on the calculated scaling rate, and each of the layers are moved in a predetermined direction at the calculated movement velocity.

Abstract: A system, method, and computer program product are provided for simulating light transport. In operation, a distribution function is decomposed utilizing a technique for sampling from a probability distribution (e.g. the Alias Method, etc.). Additionally, light transport associated with at least one scene is simulated utilizing information associated with the decomposed distribution function.

Abstract: A mobile terminal and a method of controlling the same are provided. When a touch input of starting from a predefined area on a touch screen is received, the mobile terminal scrolls at least one page including at least one item while sequentially exposing on the touch screen, but scrolls by giving a three-dimensional effect to each page. Accordingly, accessibility and utility of an item providing in the mobile terminal can be improved.

Abstract: Micropolygon splatting may involve tessellating by subdividing a mesh until triangle edges are shorter than 0.75 pixels. In some cases, rasterizing the primitive may be avoided.

Abstract: Remote rendering of three-dimensional images using virtual machines includes using a hypervisor executing on a physical computer to allocate exclusive and direct access to a graphics processing unit in the physical computer, to a first virtual machine. An agent executing on a second virtual machine intercepts three-dimensional draw commands generated by a three-dimensional application and forwards the intercepted draw commands to a rendering agent executing on the first virtual machine. The rendering agent then transmits the intercepted draw commands to the graphics processing unit for rendering upon which the graphics processing unit renders a three-dimensional image from the draw commands. The rendering agent obtains the rendered image from the graphics processing unit and forwards the image to the second virtual machine. Upon receiving the rendered image, the second virtual machine transmits the rendered image to another remote, physical computer where the rendered image is displayed to a user.

Abstract: The invention discloses a submarine topography construction method based on multi-source water depth data integration, which achieves reasonable splicing of various data such as multi-beam sounding, single-beam sounding, historical topography map and global topography and submarine topography construction. The invention comprises the following steps of: converting a historical submarine topography map into grid data, converting water depths of other sources into grids, using an overlapping and contrasting method to evaluate the accuracy of the water depths of different sources; using a multi-map-layer method to carry out integration, cutting and splicing on multi-source water depth data, constructing an error distribution model to reasonably revise and integrate various-source water depth data; and constructing multi-source water depth submarine topography and grid.

Abstract: A method for representing a terrain, a method for creating terrain primitives, and an apparatus using the methods are disclosed. The terrain representation method includes: reading digital elevation model (DEM) data of a terrain; extracting feature points of the terrain from the DEM data of the terrain; creating a plurality of terrain primitives according to the feature points of the terrain; storing terrain representation model data based on the plurality of terrain primitives; and converting the terrain primitive based terrain representation model data into DEM data, and visualizing the DEM data.

Abstract: According to one embodiment, an image processing system includes a stereoscopic display device and a control unit. The stereoscopic display device is configured to display a stereoscopic image viewed by an observer stereoscopically by displaying a predetermined parallax number of parallax images. The control unit is configured to perform control, when generating the predetermined parallax number of parallax images from volume data that is three-dimensional medical image data, so as to change a parallactic angle between parallax images based on the shape of a subject portion and to display a predetermined parallax number of parallax images at the parallactic angle thus changed on the stereoscopic display device.

Abstract: A fitting system with intelligent visual tools may included calculating a response curve of a hearing assistance device, wherein the response curve indicating sound level pressure level compared to frequency. Additionally it may include, displaying, on a display device, the response curve and displaying concurrently with the response curve, a visual cue, wherein the visual cue represents data including at least one of: gain of the response curve, a comparison between a target response curve and the response curve, and a comparison between binaural response curve.

Abstract: A method for performing occlusion queries is disclosed. The method includes steps of: (a) a graphics processing unit (GPU) using a first depth buffer of a first frame to thereby predict a second depth buffer of a second frame; and (b) the GPU performing occlusion queries for the second frame by using the predicted second depth buffer, wherein the first frame is a frame predating the second frame. In accordance with the present invention, a configuration for classifying the objects into the occluders and the occludees is not required and the occlusion queries for the predicted second frame are acquired in advance at the last of the first frame or the first of the second frame.