Described embodiments include a system that includes a display and a processor. The processor is configured to position an indicator, in response to a positioning input from a user, over a particular point on a three-dimensional electroanatomical map that is displayed on the display, and over which are displayed a plurality of markers that mark respective data points. The processor is further configured to expand a contour, subsequently, along a surface of the map, while a selecting input from the user is ongoing, such that all points on the contour remain equidistant, at an increasing geodesic distance with respect to the surface, from the particular point, and to display, on the display, one or more properties of each of the data points that is marked by a respective one of the markers that is inside the contour. Other embodiments are also described.

A virtual server includes one or more processors that execute instructions to generate a virtual desktop, and generate an active virtual monitor and a paused virtual monitor for the generated virtual desktop. A first portion of the generated virtual desktop is assigned to the active virtual monitor, and a second portion of the generated virtual desktop is assigned to the paused virtual monitor. The active and paused virtual monitors each have a respective allocated memory. The amount of memory allocated for the paused virtual monitor is less than the amount of memory allocated for the active virtual monitor. A captured image of at least one of the first and second portions of the generated virtual desktop is provided for presenting on a physical monitor of a client device.

Aspects of the present invention relate to providing see-through computer display optics.

Computer-implemented systems, methods, and computer-readable media are provided for providing virtual monitors. In accordance with some embodiments, a number of virtual monitors in which to provide a virtual desktop and a characteristic of one of the virtual monitors can be identified. A virtual monitor can then be generated based on the characteristic, and a portion of the virtual desktop can be assigned to the virtual monitor based at least in part on the identified number. An image of the portion of the virtual desktop can then be captured from the virtual monitor, and provided for presentation on a monitor of a client device.

A method for authoring and displaying a virtual tour of a three-dimensional space which employs transitional effects simulating motion. An authoring tool is provided for interactively defining a series of locations in the space for which two-dimensional images, e.g., panoramas, photographs, etc., are available. A user identifies one or more view directions for a first-person perspective viewer for each location. For pairs of locations in the series, transitional effects are identified to simulate smooth motion between the pair of locations. The authoring tool stores data corresponding to the locations, view directions and transitional effects for playback on a display. When the stored data is accessed, a virtual tour of the space is created that includes transitional effects simulating motion between locations. The virtual tour created can allow a viewer to experience the three-dimensional space in a realistic manner.

Interference-based augmented reality hosting platforms are presented. Hosting platforms can include networking nodes capable of analyzing a digital representation of scene to derive interference among elements of the scene. The hosting platform utilizes the interference to adjust the presence of augmented reality objects within an augmented reality experience. Elements of a scene can constructively interfere, enhancing presence of augmented reality objects; or destructively interfere, suppressing presence of augmented reality objects.

One embodiment of the present invention sets forth a technique for designing and generating a smart object. The technique includes receiving a first input indicating a smart object behavior of a smart object that includes a smart device embedded in a three-dimensional (3D) object; in response to the input, generating computer instructions for the smart device, wherein the computer instructions, when executed by the smart device, cause the smart object to implement the smart object behavior; and transmitting the computer instructions to the smart device.

According to an example embodiment, a sewing simulation method in a three-dimensional (3D) exploded view includes: generating a 3D exploded view in which a distance increases between at least one piece included in a design article and a plurality of patterns included in the piece; displaying a plurality of sewing lines related to a selected piece determined based on an input of selecting one piece from among the at least one piece, based on sewing line matching information, wherein the sewing line matching information includes a matching relationship between sewing lines on outlines of different patterns; and displaying a plurality of sewing lines related to a selected pattern determined based on an input of selecting one pattern from among the plurality of patterns, based on the sewing line matching information.

A method and apparatus for applying a two-dimensional image on a three-dimensional model composed of a polygonal mesh. The method comprises generating an adjacency structure for all triangles within the mesh, identifying a triangle within membrane containing the desired center point, calculating spatial distances between the three vertices and desired center checking each triangle edge to see if the distances show an intersection, if a collision is detected add the triangle to the list and iteratively processing all the triangles in the list calculate the spatial data of the single unknown vertex, check the two edges of the triangle to see if the calculated distances show an intersection, if an intersection occurs add this new triangle to the list; transforming into UV-coordinates; and applying the two-dimensional image to the three-dimensional model using the UV-coordinates.

A system configured to provide effects for virtual content in an interactive space may comprise one or more of a headset, one or more image-forming components, one or more physical processors, and/or other components. An image forming virtual object may be presented to the user via the one or more image-forming components. The virtual object may be perceived as being present in the real world. A user may utilize a virtual tool to apply an exploder effect and/or other effect. The virtual tool providing the exploder effect may take the form of a rod-shaped object forming a wand. The virtual tool may be inserted into the virtual object. the virtual tool may be drawn away from the virtual object to cause the virtual object to achieve an exploded view state.