A novel vehicle onboard holographic communication system is configured to generate, manage, and display various three-dimensional holographic objects, holographic digital assistance, and dynamically-updatable holographic contents in automotive infotainment, vehicle control, and occupant communication environments. Preferably, the vehicle onboard holographic communication system includes a vehicle infotainment hardware module, a vehicle infotainment operating system (e.g. Apple CarPlay, Android Auto, etc.) and a vehicle onboard holographic communication operating system (e.g. HoloDash OS) executed in a CPU and a memory unit of the vehicle infotainment hardware module, and a holographic display pod integrated into a vehicle dashboard or another part of the vehicle interior. The in-vehicle holographic display pod provides lifelike high-resolution 3D holographic objects for vehicle occupant infotainment, vehicle control, and communication applications. Furthermore, the vehicle onboard holographic communication system allows in-vehicle holograms to receive and interpret driver or passenger gesture commands with embedded sensors, which enable bilaterally-interactive experiences with the in-vehicle holograms.

The present invention relates to one or multiple customizable interactive three-dimensional (3D) visualization and multi-sensory technologies useful in a variety of applications, including medical applications and e-commerce. In addition to visualization (which is a common sensory output for all technologies used in the present invention), a number of additional sensory data can be derived including (but not limited to) taste, hearing, smell, vibration, and motion. From this multi-sensory data, in combination with 3D imagery, a myriad of applications can be derived for interactive analysis, including the creation, modification, testing, comparison, query, analysis, and refinement of imaging data, on an individual or collective basis.

Systems, methods, and computer-readable media are disclosed for controlling parameters of a holographic image. A gaze direction of a user is detected and user interaction data indicative of the gaze direction of the user is generated. A determination is then made using the user interaction data that the gaze direction of the user at least partially coincides with an object of interest. A further determination is made that the object of interest is at least partially obscured by the holographic image. One or more of the parameters of the holographic image are then adjusted to enhance visibility of the object of interest to the user.

Computer systems, methods, and storage media for rendering a holographic object in accordance with a physical relationship between the holographic object and an identified physical object. Virtual properties are assigned to a physical object, and in response to detecting a change to the physical relationship between the holographic object and the physical object, the holographic object is rendered according to a modification defined, at least in part, by the change to the physical relationship and by the properties assigned to the physical object.

An optical system comprises an imaging holographic optical element, which produces a floating hologram. An upstream light-forming holographic optical element causes spectral filtering of the light.

Selecting a user to control a 3D holographic object of a plurality of 3D holographic objects projected in midair above a central point of a location by a projector when multiple users attempt to manipulate the same 3D holographic objects. Identification of the users and a policy regarding manipulation of the 3D holographic objects selected by more than one user are evaluated. For each of the 3D holographic objects selected by multiple users, a queue of interactions requested by the multiple users is generated during interactions of a single user with the 3D holographic object; and the interactions requested by the user with a highest priority of the multiple users are executed to manipulate the selected 3D holographic object.

A method for displaying a hologram to a variable direction including using circuitry to determine a direction from a holographic projector to a viewer for projecting a hologram to a viewer, and projecting a hologram in the determined direction, in which the projecting the hologram includes reflecting from a same mirror as the determining the direction of the viewer, and the circuitry controls the projecting the hologram to a direction corrected for a difference in direction between a projecting unit and a tracking unit relative to the mirror. Related apparatus and methods are also described.

Disclosed are a mobile terminal having a hologram output unit and a method for controlling the same. The mobile terminal, comprises: a hologram output unit configured to output a hologram object to an output space outside the mobile terminal; an image sensor configured to sense a portion of a human body located within the output space of the hologram object; a feedback output unit configured to output a feedback signal; and a controller configured to: determine a relative position between the hologram object output by the hologram output unit and the portion of the human body sensed by the image sensor; detect, based on the relative position between the hologram object and the portion of the human body, that the portion of the human body approaches the hologram object, and control, based on the detection that the portion of the human body approaches the hologram object, the feedback output unit to transmit the feedback signal towards the portion of the human body that is detected to approach the hologram object.

Methods and systems are described for improved techniques for consuming and interacting with media content. Specifically, a media guidance application may present a holographic structure using a holographic interface. Moreover, the media guidance application may monitor the user and/or area about the holographic interface for user interactions that may cause the media guidance application to alter the holographic structure based on a user interaction. The media guidance application may also after altering the holographic structure, generate for display a media asset associated with the holographic structure.

Systems, methods, and computer-readable media are disclosed for generating or modifying a holographic object based on user commands. Holographic projectors, which may be integrated with a user device, may be controlled to project a holographic grid that can be manipulated by a user to provide design commands to the user device. The user device may be configured to interpret the design commands and generate a holographic object based thereon. The holographic grid may include a plurality of cuboid cells. A user may, through gesture-based commands, indicate, for any given cell in the holographic grid, whether or not a portion of the holographic object should be generated in a three-dimensional spatial position corresponding to the cell. In addition, a user can provide gesture-based commands to selected cells of the holographic grid corresponding to portions of an existing holographic object that the user wishes to remove.