Abstract: An image processing method includes: determining whether a draw command that is identical to a previous draw command is input; obtaining information about a transparency of a previous frame that is performed with the previous draw command; and performing image processing on a current frame based on the information about the transparency.

Abstract: Systems, devices, and methods obtain a sequence of images of a physical scene that includes a physical representation of a first object; calculate a sequence of first transform values of the physical representation of the first object based on the sequence of images store the sequence of first transform values; generate an enhanced scene; maintain the first object in the enhanced scene at positions and orientations that are indicated by the sequence of first transform values; receive an indication of selected transform values in the sequence of first transform values; retrieve the selected transform values; and generate a replay image of the enhanced scene, from a second observer viewpoint, that shows the first object at the position and the orientation that are indicated by the selected transform values.

Abstract: In one aspect, an HMD is disclosed that provides a technique for generating a composite image representing the view of a wearer of the HMD. The HMD may include a display and a front-facing camera, and may be configured to perform certain functions. For instance, the HMD may be configured to make a determination that a trigger event occurred and responsively both generate a first image that is indicative of content displayed on the display, and cause the camera to capture a second image that is indicative of a real-world field-of-view associated with the HMD. Further, the HMD may be configured to generate a composite image that combines the generated first image and the captured second image.

Abstract: A method for visualizing flow data from computation fluid dynamics (CFD) applications in 2-dimensions (2D) includes receiving a 3-dimensional (3D) image volume from a CFD simulation of fluids flowing through vessels in a patient that is a snapshot of a fluid flow in the vessels at a certain time, subdividing the 3D image volume into 3D data blocks, minimizing a sum over a matrix of energy interactions defined for each pair of data blocks in the 3D image volume, where the minimization preserves a local shape of the vessels, where minimizing the sum over the matrix of energy interactions is performed on a graphics processing unit (GPU), and using the minimized energy interaction matrix to display on a monitor a 2D sketch of the 3D image volume, where the 2D sketch is displayed in real-time with respect to the time scale of the CFD simulation.

Abstract: A storage medium encoded with a display control program and executable by a computer of a display control device capable of interacting with an input device, for controlling a display capable of providing stereoscopic display, is provided. The present display control program stored in the storage medium includes zoom control instructions for performing zoom processing of a stereoscopic image based on an operation input accepted by operation input acceptance instructions, parallax control instructions for adjusting parallax of the stereoscopic image based on the operation input accepted by the operation input acceptance instructions, and display control instructions for causing the display to display the stereoscopic image subjected to zoom processing in accordance with the zoom control instructions, with parallax adjusted in accordance with the parallax control instructions.

Abstract: Systems, methods, and apparatus for performing queries in a graphics processing system are disclosed. These systems, methods, and apparatus may be configured to read a running counter at the start of the query to determine a start value, wherein the running counter counts discrete graphical entities, read the running counter at the end of the query to determine an end value, and subtract the start value from the end value to determine a result.

Abstract: Various embodiments include systems and methods for adaptive visualization enhancement in volumetric ultrasound images. One or more structures may be determined or identified to be visually enhanced in the volumetric ultrasound images, and one or more visualization changes may be determined, for each of the one or more structures to be visually enhanced. Rendering adjustments required to achieve each of the one or more visualization changes, for each of the one or more structures to be visually enhanced, may then be determined; and the rendering adjustments may be applied during volume rendering of the volumetric ultrasound images.

Abstract: One variation of a method for reducing perceived optical distortion of light output through a dynamic tactile interface includes: rendering an image on a digital display coupled to a substrate opposite a tactile layer, the tactile layer defining a tactile surface, a peripheral region, and a deformable region adjacent the peripheral region, disconnected from the substrate, and operable between a retracted setting and an expanded setting, the deformable region substantially flush with the peripheral region in the retracted setting and offset above the peripheral region in the expanded setting; estimating a viewing position of a user relative to the digital display; transitioning the deformable region from the retracted setting into the expanded setting; and modifying the portion of the image rendered on the digital display according to the estimated viewing position of the user and a profile of the tactile surface across the deformable region in the expanded setting.

Abstract: One or more systems, devices, and/or methods for generating a map including path side data include storing path side data referenced to three-dimensional geographic coordinates. The path side data may be optical data or optical data modified based on one or more panoramic images. The path side data is combined with map data received from a map database. The map data includes nodes and segments. A processor rotates the path side data based on one of the segments. The rotation may be about the segment or about a featured identified in the optical data. The path side data overlaid on the map data is outputted to a display, a file, or another device.

Abstract: A method and systems of applying a contour gradient to a two-dimensional path are provided. A three-dimensional polygonal shell may be constructed from the two-dimensional path. Then the three-dimensional polygonal shell may be projected into two dimensions, resulting in a two-dimensional projected model, while saving values for a third dimension for each point in the two-dimensional projected model. Then a range of all values for the third dimension in the two-dimensional projected model is determined from the saved values. The range can then be mapped to a visual attribute. The two-dimensional projected model may be displayed using the mapped visual attribute.

Abstract: To provide smoothly scaleable map features on interactive digital maps, a first and a second sets of style parameters for rendering a map feature at a first zoom level and a second zoom level, respectively, are received. The first and second sets of style parameters are provided to a vertex shader. The vertex shader is configured to interpolate the first set of style parameters and the second set of style parameters to generate an interpolated set of style parameters for a certain zoom level between the first zoom level and the second zoom level, and render the map feature at the certain zoom level in accordance with the interpolated set of style parameters.

Abstract: A method for generating masking image using general polygonal mask includes receiving a pixel of a raw image and a polygon vertices array corresponding to a polygonal mask, determining whether the pixel is inside the polygonal mask, labeling the pixel to be a masked pixel if the pixel is inside the polygonal mask, or labeling the pixel to be a visible pixel if the pixel is outside the polygonal mask, and outputting the masked pixel or the visible pixel to generate the masking image.

Abstract: Systems, methods, and computer programs are disclosed for providing secure access control to a graphics processing unit (GPU). One system includes a GPU, a plurality GPU programming interfaces, and a command processor. Each GPU programming interface is dynamically assigned to a different one of a plurality of security zones. Each GPU programming interface is configured to receive work orders issued by one or more applications associated with the corresponding security zone. The work orders comprise instructions to be executed by the GPU. The command processor is in communication with the plurality of GPU programming interfaces. The command processor is configured to control execution of the work orders received by the plurality of GPU programming interfaces using separate secure memory regions. Each secure memory region is allocated to one of the plurality of security zones.

Abstract: Systems and methods are used to display cell structures of a biological cell. A plurality of cell structures of a biological cell is stored and for each cell structure of the plurality of cell structures one or more stain colors are stored. A selected cell structure is received from an input device. One or more stain colors of the selected cell structure are retrieved. The one or more stain colors of the selected cell structure are displayed. A selected stain color is received from the input device. The selected cell structure is displayed in the selected stain color in an exemplary cell image. Further, a three-dimensional image of a biological cell is stored. The three-dimensional image is displayed on a display that includes a touch screen. A movement selection is received from the touch screen. The three-dimensional image is displayed on the display according to the movement selection.

Abstract: Embodiments of the present invention provide a method for color calibration and a user terminal, which relate to the field of terminal display and are capable of compensating the colors of the displayed content on a screen according to the external light intensity, preventing content color distortion, and improving user experience. The embodiments of the present invention are used by a mobile terminal to calibrate screen colors according to external light.

Abstract: The invention provides a system and method that allows for the calibration of color and intensity in a display system in a manner that is practical for the user, and handling obscuring factors, giving the user the ability to make intelligent trade-offs, and making it possible to quickly and efficiently re-compute a correction. More generally, correction and adjustment of intensity and color non-uniformities, and using optical sensor feedback to detect and correct for those changes is contemplated. This includes, but is not limited to, showing very bright images and very dark images. This invention further provides methods for making a practical system for the user, including a method of calculating corrections, dealing with obscuring factors that can affect the calculation process, providing information to allow users to make decisions on how to make trade-offs on the quality factors of the display, and allowing fast re-calculation of intensity corrections when re-calibrating.

Abstract: Systems and methods for customizing animation variables and modifications to animation variables in an animation system are provided. An animated model may be comprised of a hierarchical structure of rigs and sub-rigs. An animator may customize the location of animation variables within the hierarchical structure through a relocation operation from an original position to a relocated position. The animation system identifies the relocation operation, resulting in an association being generated between the original position and the relocated position. Modifications made to animation variables in the animation system may be received by the animation system and the animator can customize the scope of the modification and its application to the animated model or animated scene.

Abstract: In an embodiment, a display control device includes: a control unit configured to control the display and output of image data; a display information generating unit configured to generate display information including at least an image ID for identifying the image data and a display period whenever the image data is output by the control unit for display; and a transmitting unit configured to transmit the display information to an external device so that the display information is managed by the external device as one unit information item serving as a unit of image formation together with other display information items having a predetermined relation with the display information.

Abstract: The present disclosure describes methods and systems, including computer-implemented methods, computer-program products, and computer systems, for providing 360-degree well core sample photo image integration, calibration, and interpretation for modeling of reservoir formations and lithofacies distribution. One computer-implemented method includes receiving a 360-degree well core sample photo image, geospatially anchoring, by a computer, the received 360-degree well core sample photo image, decomposing, by a computer, the geospatially-anchored 360-degree well core sample photo image into a color numerical array, transforming, by a computer, the color numerical array into a formation image log, calibrating, by a computer, the formation image log for consistency with additionally available data, and generating, by a computer, 3D lithofacies interpretation and prediction data using the formation image log.

Abstract: In one aspect, an HMD is disclosed that provides a technique for generating a composite image representing the view of a wearer of the HMD. The HMD may include a display and a front-facing camera, and may be configured to perform certain functions. For instance, the HMD may be configured to make a determination that a trigger event occurred and responsively both generate a first image that is indicative of content displayed on the display, and cause the camera to capture a second image that is indicative of a real-world field-of-view associated with the HMD. Further, the HMD may be configured to generate a composite image that combines the generated first image and the captured second image.