A light field (LF) display system for displaying holographic content (e.g., a holographic sporting event or holographic content to augment a holographic sporting event) to viewers in an arena. The LF display system in the arena includes LF display modules tiled together to form an array of LF modules. The array of LF modules create a holographic object volume for displaying the holographic content in the arena. The array of LF modules displays the holographic content to viewers in the viewing volumes. The LF display system can be included in a LF sporting event network. The LF sporting event network allows holographic content to be created at one location and presented at another location. The LF sporting event network includes a network system to manage the digital rights of the holographic sporting event content.

This application includes an interactive control method and apparatus, a storage medium, and an electronic device. In these method, apparatus, storage medium, and device, a touch operation performed on a touch panel is recognized. A holographic projection device is configured to display a holographic projection-based virtual character. The touch panel is disposed on the holographic projection device. An interaction request is generated according to the recognized touch operation. The interaction request corresponds to an interaction with the holographic projection-based virtual character. Further the holographic projection-based virtual character is controlled to perform an interactive action associated with the interaction request.

A video communication system uses a light field display to present a holographic image of a remote scene (e.g., a hologram of a remote participant). The system may include a local light field display assembly and a controller. The controller generates display instructions based on visual data corresponding to a remote scene received from a remote image capture system (e.g., a remote light field display system). The display instructions cause the local light field display assembly to generate a holographic image of the remote scene.

A display device is disclosed. The display device comprises an optical structure with a plurality of pixels configured to generate an optical image on a front side of the optical structure. The display device further includes a plurality of acoustic transducers configured to generate an acoustic field for stimulating the tactile sense of a human person based on a plurality of control signals in a space in front of the front side of the optical structure. The plurality of acoustic transducers are located on a back side of the optical structure. The display device further includes a control circuit configured to generate at least one of the plurality of control signals based on at least one acoustic property of the optical structure.

One or more signals are received from one or more sensors. Based at least in part on the one or more signals, a location of a person relative to one or more locations of an autonomous self-moving device is determined. Based at least in part on the one or more signals, data indicative that the autonomous self-moving device has detected a presence and location of the person is generated. Based at least in part on the one or more signals, a location of a person relative to a location of the autonomous self-moving device is determined. A planned path for the autonomous self-moving device is determined. Based at least in part on the one or more signals, data indicative of the planned path is generated.

A video communication system uses a light field display to present a holographic image of a remote scene (e.g., a hologram of a remote participant). The system may include a local light field display assembly and a controller. The controller generates display instructions based on visual data corresponding to a remote scene received from a remote image capture system (e.g., a remote light field display system). The display instructions cause the local light field display assembly to generate a holographic image of the remote scene.

A light filed (LF) display system for displaying holographic content to viewers in an amusement park (e.g., as part of an amusement park ride). The LF display system in an amusement park includes LF display modules tiled together to form an array of LF modules. In some embodiments, the LF display system includes a tracking system and/or a viewer profiling module. The tracking system and viewer profiling module can monitor and store characteristics of viewers on the amusement park ride, a viewer profile describing a viewer, and/or responses of viewers to the holographic content during the amusement park ride. The holographic content created for display on an amusement park ride can be based on any of the monitored or stored information.

The interactive holographic human-computer interface (H2CI) has the following key capabilities: 1. Support for multiple applications just as today's human-computer interfaces support any application that is developed for the computer 2. Provision of the convenience, efficiency, combined data display and input interface of virtual physical controls (displayed as holograms) 3. Interaction with the virtual physical controls, as the actual interface to the local or external system, would also result in changes to the system being controlled, not just in the displayed holograms 4. Use of sensor feedback (in realtime, under computer control), including EMR emission and detection, to allow synchronization of physical objects with each other, under the control of virtual objects representing both the targets and tools or instruments to manipulate them 5. holographic interface that would distinguish the type of motion 6. Emission and detection, probably with EMR, of simulated electrical, vibration, or other physical phenomena characteristic of the physical objects represented by the displayed holograms.

In order to accomplish these capabilities, the H2CI uses a combination of software and hardware components to track the motion, type of motion, location, and dwell time of a Command Object relative to a displayed hologram. This allows the H2CI to distinguish, in realtime, without human intervention, intended from unintended motions as well as which of multiple displayed holograms is of interest to a Command Object controlled by the user. In addition, emission and detection of EMR would permit the exchange of information among virtual objects in addition to their proximity to each other or beyond the physical capacity of the motion detector configuration, independently of the motion detector

A method, system and program for producing an interactive three-dimensional holographic image, including the steps of generating, by one or more processors of a computer system, a virtual object and assigning physical properties to the virtual object using metadata. Signals are received from a virtual tool to determine a position of the virtual tool. Interactive force between the virtual tool and the virtual object are calculated based on the signals from the virtual tool and the position of the virtual tool. A modified virtual object is generated based on the interactive forces and the physical properties, and the modified virtual object is displayed as a holographic image. The system may also determine a force feedback according to the position of the virtual tool in relation to the virtual object, send the force feedback to a user through a haptic interface device; and update the force feedback according to movement of the virtual tool in real space.

Systems and methods are provided for selectively controlling a carry mode for holograms presented in mixed-reality environments and for providing leashing buffers for the holograms. The carry mode enables holograms to be functionally moved within a single mixed-reality environment, and out into one or more different mixed-reality environments. The carry mode can be automatically applied to holograms created within the mixed-reality environment. The carry mode can also be applied responsive to user input applied to world-locked holograms, which triggers a switch from the world-locked mode to the carry mode from. Holograms can also be leashed for persistently displaying holograms associated with or linked to a user in the mixed-reality environment to provide the user increased accessibility to the hologram while navigating within and without a particular mixed-reality environment. Selectable options are presented with a hologram in carry mode for switching from the carry mode to the world-locked mode.