A method, apparatus, and computer program product are provided for adaptive zoom control for zooming in on a venue beyond the maximum zoom level available in a digital map. An apparatus may be provided including at least one processor and at least one non-transitory memory including computer program code instructions. The computer program code instructions may be configured to, when executed, cause the apparatus to at least: provide for presentation of a map of a region including a venue; receive an input corresponding to a zoom-in action to view an enlarged portion of the region, where the enlarged portion of the region includes the venue; and in response to receiving the input corresponding to a zoom-in action to view the enlarged portion of the region, transition from the presentation of the map of the region to a presentation of a venue object corresponding to the venue.

Communicating information through a user platform by representing, on a user platform visual display, spatial publishing objects as entities at locations within a three-dimensional spatial publishing object space. Each spatial publishing object associated with information, and each presenting a subset of the associated information. Establishing a user presence at a location within the spatial publishing object space. The user presence, in conjunction with a user point-of-view, being navigable by the user in at least a two-dimensional sub-space of the spatial publishing object space.

There is provided an image processing device including: a data storage unit storing feature data indicating a feature of appearance of one or more physical objects; an environment map building unit for building an environment map based on an input image obtained by imaging a real space and the feature data, the environment map representing a position of a physical object present in the real space; a control unit for acquiring procedure data for a set of procedures of operation to be performed in the real space, the procedure data defining a correspondence between a direction for each procedure and position information designating a position at which the direction is to be displayed; and a superimposing unit for generating an output image by superimposing the direction for each procedure at a position in the input image determined based on the environment map and the position information, using the procedure data.

In one implementation, a method for improved motion planning. The method includes: obtaining a macro task for a virtual agent within a virtual environment; generating a search-tree based on at least one of the macro task, a state of the virtual environment, and a state of the virtual agent, wherein the search-tree includes a plurality of task nodes corresponding to potential tasks for performance by the virtual agent in furtherance of the macro task; and determining physical motion plans (PMPs) for at least some of the plurality of task nodes within the search-tree in order to generate a lookahead planning gradient for the first time, wherein a granularity of a PMP for a respective task node in the first search-tree is a function of the temporal distance of the respective task node from the first time.

A virtual environment platform may receive, from a user device, a request to access a virtual reality (VR) environment and may verify, based on the request, a user of the user device to allow the user device access to the VR environment. The virtual environment platform may receive, after verifying the user of the user device, user voice input and user handwritten input from the user device. The virtual environment platform may generate processed user speech by processing the user voice input, wherein a characteristic of the processed user speech and a corresponding characteristic of the user voice input are different and may generate formatted user text by processing the user handwritten input, wherein the formatted user text is machine-encoded text. The virtual environment platform may cause the processed user speech to be audibly presented and the formatted user text to be visually presented in the VR environment.

An interactive virtual world having avatars. Scenes in the virtual world as seen by the eyes of the avatars are presented on user devices controlling the avatars. In one approach, a method includes identifying a location of an avatar in a virtual world, and a point of gaze of the avatar; adjusting, based on the point of gaze, a lens that directs available light received by the lens so that the lens can focus on objects at all distances; collecting, using the adjusted lens, image data; and generating a scene of the virtual world as seen by the avatar, the scene based on the collected image data, the location of the avatar, and the point of gaze of the avatar.

The present technology relates to an image processing apparatus and a file generation apparatus that make it possible to appropriately reproduce a BV content. An image processing apparatus includes: a file acquisition unit that acquires a file having a management region where information for management of a 3D object content is stored and a data region where a track in which streams included in the 3D object content are stored is stored, group information for selection, from a plurality of the streams included in the 3D object content, of the stream appropriate for reproduction of the 3D object content being stored in the management region; and a file processor that selects a plurality of the streams to be used for reproduction of the 3D object content on the basis of the group information. The present technology is applicable to a client apparatus.

Presented herein are methods, systems, devices, and computer-readable media for image management in image-guided medical procedures. Some embodiments herein allow a physician to use multiple instruments for a surgery and simultaneously provide image-guidance data for those instruments. Various embodiments disclosed herein provide information to physicians about procedures they are performing, the devices (such as ablation needles, ultrasound transducers or probes, scalpels, cauterizers, etc.) they are using during the procedure, the relative emplacements or poses of these devices, prediction information for those devices, and other information. Some embodiments provide useful information about 3D data sets and allow the operator to control the presentation of regions of interest. Additionally, some embodiments provide for quick calibration of surgical instruments or attachments for surgical instruments.

A human-machine interaction, HMI, user interface (1) connected to at least one controller or actuator of a complex system (SYS) having a plurality of system components, C, represented by associated blocks, B, of a hierarchical system model (SYS-MOD) stored in a database, DB, (5) said user interface (1) comprising: an input unit (2) adapted to receive user input commands and a display unit (3) having a screen adapted to display a scene within a three-dimensional workspace, WS.sub.B1, associated with a selectable block, B1, representing a corresponding system component, C, of said complex system (SYS) by means of a virtual camera, VC.sub.B1, associated to the respective block, B1, and positioned in a three-dimensional coordinate system within a loaded three-dimensional workspace, WS.sub.B1, of said block, B1, wherein the virtual camera, VC.sub.B1, is moveable automatically in the three-dimensional workspace, WS.sub.B1, of the associated block, B1, in response to a user input command input to the input unit (2) of said user interface (1) to perform a zooming operation on the respective block, B1, to reveal or hide its content areas, CAs, wherein the content areas, CAs, of the zoomed block, B1, include nested child blocks, B1_1, B1_2, of the respective block, B1.

Swimming pools can be visualized according to some aspects described herein. In one example, a system can receive a user selection of a particular liner from among a plurality of liner options for a virtual swimming pool. The system can generate a virtual swimming pool having the particular liner. The virtual swimming pool can be a three-dimensional (3D) rendering of a swimming pool with the particular liner. The system can then output the virtual swimming pool for display on a display device.