Abstract: A method of generating a smooth optimized part design for a workpiece is presented. Topology optimization is performed based on design objectives, to generate surface data describing an optimized but unfinished surface of the workpiece. The surface data is used to generate volumetric data describing the workpiece structure. A three dimensional smoothing filter is applied to the volumetric data. A manufacturing design is generated from the resulting smoothed volumetric data.

Abstract: In one example embodiment, a method for visualizing using a rendering technique in which voxels are sampled along a ray through a volume, the method includes obtaining voxel data, modifying a first portion of the voxel data, the first portion of the voxel data associated with a first segmentation mask. The modifying includes setting the first portion of the voxel data to at least one of a plurality of permitted voxel values. The method further includes applying a set of operators to the modified first portion of the voxel data and a remaining portion of the voxel data and displaying the volume based on the applied first set of operators.

Abstract: An information processing apparatus acquires a 2D image as a definition target of depth information, and accepts, for the acquired 2D image, an input of point information for designating two points on the image and an input of line segment information indicating a first line segment as a standard of a depth. The apparatus sets, for a point on a second line segment connecting the two points on the 2D image indicated by the point information, depth information based on the first line segment indicated by the line segment information.

Abstract: A computer readable recording medium stores a program that causes a computer to execute a process. The process includes: voxelizing a three-dimensional model to generate a voxel model; performing inversion processing on an area in three-dimensional space including the generated voxel model to invert an area set as voxels and an area not set as voxels; extracting an area including specific two points from the area set as voxels after the inversion processing, the area to be extracted allowing center of a specific sphere having a predetermined size to pass anywhere therein; determining a shortest path between the specific two points within the extracted area; and outputting the shortest path.

Abstract: Systems and methods for projecting planar and 3D images through water or liquid onto a surface include creating a 3D model of the body of liquid and surface and 3D models of creative elements to be used in scenes. Animating the 3D models of the creative elements, placing them inside the 3D model of the body of liquid. Lighting the animated creative elements, rendering planar animations of the modeled creative elements and, using projection and texturing software, virtually projecting the planar animations back onto the surface of the 3D model of the body of liquid from the same camera position in order to “bake in” a warped transformation of the digitally rendered planar animations. Digitally rendering a 3D animation of the warped, transformed planar animations, and playing or looping the digitally rendered 3D animation through the body of liquid on a digital video player or digital server.

Abstract: A computer-implemented method, according to one embodiment, includes: generating two or more sample graphs by sampling edges of a current snapshot of a dynamic graph, generating two or more partial results by executing an algorithm on the two or more sample graphs, combining the partial results into a final result, and incrementally maintaining the sample graphs. Edges included in the current snapshot of a dynamic graph and which were added to the dynamic graph in a most recent update thereto are included in each of the generated two or more sample graphs. Moreover, incrementally maintaining the sample graphs includes: subsampling each of the edges of each of the sample graphs at a given time by applying a Bernoulli trial, and combining a result of the subsampling with new edges received in a batch corresponding to the given time to form new sample graphs.

Abstract: A method for making a three-dimensional surface reconstruction of an object from two or more bi-dimensional images of the object, so called 2D images, comprising: a) providing a three-dimensional dataset, so called 3D dataset, of the object; b) generating a 3D model using the dataset as described in a); c) providing motion information to build a 3D model over time; d) generating a 3D reconstruction from said at least two 2D images; and e) using information from the 3D model over time to correct the 3D reconstruction over time. A corresponding apparatus and computer program are also disclosed and claimed.

Abstract: A computer-implemented method, a computer program product and a computer system for installing a first physical element on or in a second physical element are provided. The method comprises receiving, by an augmented reality system, an indication of at least one of the first physical element and the second physical element. The method further comprises loading, by the augmented reality system and using the indication, a model of the second physical element. The method further comprises recognizing, by the augmented reality system, the second physical element based on the model. The method further comprises projecting, by the augmented reality system, an image corresponding to the first physical element on or in the second physical element.

Abstract: A method and apparatus for processing a three-dimensional image are provided. The method includes receiving original color data and original depth data of a plurality of layers of an original holographic image, selecting reference layers from among the plurality of layers, mapping adjustment color data of a non-selected layer, which is determined based on using the original depth data of the non-selected layer and the reference layers, to each of the reference layers, and generating a computer generated hologram image by using the original color data of the reference layers and the adjustment color data that has been mapped to the reference layers.

Abstract: Examples disclosed relate to displaying virtual objects. One example provides, on a display device comprising a camera and a display, a method comprising acquiring, via the camera, image data imaging an environment, receiving a user input requesting display of a three-dimensional virtual object, comparing dimensional information for the three-dimensional virtual object to dimensional information for a field of view of the display device, modifying the three-dimensional virtual object based upon comparing the dimensional information for the three-dimensional virtual object to the dimensional information for the field of view to obtain a modified three-dimensional virtual object, and displaying the modified three-dimensional virtual object via the display.

Abstract: A surrounding risk displaying apparatus includes an environment recognizer, a surrounding risk recognizer, and a display. The environment recognizer is capable of recognizing an environment around a vehicle. The surrounding risk recognizer is capable of extracting risk objects each having a risk potential not less than a predetermined risk potential, estimating a distribution of the risk potential around each of the risk objects, and calculating a risk approaching determination value that increases depending on relative approaching of the risk objects. The display is capable of displaying images in a superimposed fashion on the corresponding risk objects. The images each indicate the distribution of the risk potential around corresponding one of the risk objects.

Abstract: A near-eye light field display for use with a head mounted display unit with enhanced resolution and color depth. A display for each eye is connected to one or more actuators to scan each display, increasing the resolution of each display by a factor proportional to the number of scan points utilized. In this way, the resolution of near-eye light field displays is enhanced without increasing the size of the displays.

Abstract: During tracing of a primary ray in a 3-D space (e.g., a 3-D scene in graphics rendering), a ray is found to intersect a primitive (e.g., a triangle) located in the 3-D space. Secondary ray(s) may be generated for a variety of purposes. For example, occlusion rays may be generated to test occlusion of a point of intersection between the primary ray and primitive is illuminated by any of the light(s). An origin for each secondary ray can be modified from the intersection point based on characteristics of the primitive intersected. For example, an offset from the intersection point can be calculated using barycentric coordinates of the intersection point and interpolation of one or more parameters associated with vertices defining the primitive. These parameters may include a size of the primitive and differences between a geometric normal for the primitive and a respective additional vector supplied with each vertex.

Abstract: The system includes imaging unit configured to image a work space at a viewpoint position in a visual line direction of a worker together with a workpiece, a position attitude information obtaining unit configured to obtain a position attitude information which indicates a relative position attitude relation between a viewpoint of the worker and the workpiece in the work space, a virtual image generating unit configured to generate a three-dimensional virtual image which indicates a completed shape of the workpiece in the viewpoint position and the visual line direction of the worker based on the position attitude information, an image composing unit configured to generate a composite image by superimposing the virtual image on a real image of the work space, and a display unit configured to display the composite image. According to the system, efficiency of workpiece machining work can be considerably improved by using the mixed reality technology.

Abstract: A method for determining a residual image level of a display device and a detection device. The method includes: lighting the display device based on a setting image type, and setting a plurality of detection positions on the display device based on the setting image type; converting a display image on the display device into a grayscale image with a setting level; detecting an actual brightness value of each detection position within a setting time after converting into a grayscale of the setting level; for each detection position, acquiring a brightness variation index of the detection position based on the acquired actual brightness value and a corresponding predetermined relationship between the actual brightness value and a theoretical brightness value of the grayscale of the setting level; and acquiring an residual image level of the display device in the grayscale of the setting level based on the acquired brightness variation index.

Abstract: Systems and methods are provided for rendering graphics in augmented reality software based on the movement of a device in relation to a target object, in order to produce more desired rendering effects. An augmented reality graphic can be both scaled and shifted laterally compared to the target based on a position of the device, and can then be cropped to match the target. Scaling and shifting related to movement parallel to the target can be performed using a first (parallel) function, and scaling and shifting related to movement toward and away from the target can be performed using a second (perpendicular) function. Both functions can be chosen to ensure that an edge of the augmented image is not passed over so as to provide blank space.

Abstract: According to various embodiments of the invention, a system and method are provided for enabling interaction with, manipulation of, and control of depth-assigned content in depth-enhanced pictures, such as virtual reality images. Depth-assigned content can be assigned to a specified depth value. When a depth-enhanced picture is refocused at a focus depth substantially different from the specified assigned depth value, the depth-assigned content may be omitted, grayed out, blurred, or otherwise visually distinguished. In this manner, content associated with an in-focus image element can be visually distinguished from content associated with an out-of-focus image element. For example, in at least one embodiment, depth-assigned content is visible only when an image element associated with the content is in focus (or nearly in focus).

Abstract: In one aspect, a computer-implemented method for efficiently rendering and displaying multiple images on an electronic device having an automultiscopic display may generally include detecting, with the electronic device, a position of at least one eye relative to the automultiscopic display. The automultiscopic display may include an array of multipixels, with each multipixel including a plurality of sub-multipixels. In addition, the method may include rendering a viewpoint-specific image for each detected eye position and selectively coloring at least one sub-multipixel within one or more of the multipixels such that colors associated with the rendered viewpoint-specific image are only displayed within a multipixel display zone defined for each of the one or more multipixels with respect to each detected eye position.

Abstract: Provided is an image processing apparatus that may determine whether indirect lights are to be assigned to tiles for tile-based deferred rendering. For example, the image processing apparatus includes a calculator configured to calculate a correlation based on at least one of a first vector representing an object normal direction of a tile to be rendered and a second vector corresponding to a normal vector of an indirect light to be determined to be assigned to the tile, and a determiner configured to determine whether the indirect light is to be assigned to the tile by comparing the correlation to a threshold value.

Abstract: An apparatus and a method for providing information are provided. The apparatus includes an interfacing unit configured to receive biometric information, which is measured by an external measuring device, corresponding to a health condition of a body part of a user, from the external measuring device; and a processor configured to determine a visual metaphor representation for characterizing a degree of the health condition based on mapping information between components of the visual metaphor representation and types of the received biometric information, and transform the received biometric information into the determined visual metaphor representation, where the interfacing unit is configured to transmit the transformed visual metaphor representation to an external displaying device.