Abstract: According to one implementation, an image generation system includes a rotor, a base including a motor for spinning the rotor about an axis of rotation, a display secured to the rotor, the display including a display surface, and a blur screen secured to the display. The blur screen has a vertical edge substantially parallel to the axis of rotation and includes a first light emission barrier, a second light emission barrier, and a horizontal gap having a width substantially perpendicular to the vertical edge separating the first light emission barrier from the second light emission barrier. The first light emission barrier and the second light emission barrier are configured to substantially prevent rotational blur of an image displayed by the display surface while the display and the blur screen are spun by the motor and the rotor.

Abstract: According to one implementation, an image generation system includes a rotor and a motor for spinning the rotor about an axis of rotation, and a display secured to the rotor. The display includes a display surface and a display aperture, a first privacy s screen situated at the display surface and having a convex curvature relative to light emitted from the display surface, and a second privacy screen situated between the first privacy screen and the display aperture and having a concave curvature relative to light emitted from the display surface. The first privacy screen and the second privacy screen are configured to substantially prevent rotational blur of an image displayed by the display surface while the display is spun by the motor and the rotor.

Abstract: A stability controlled system includes a computing platform having a hardware processor, a memory storing a software code, a moveable component, and a tilt sensor. The hardware processor executes the software code to monitor the tilt sensor to determine whether the system is at a tilt with respect to a support surface for the system. When the tilt sensor is sensing the tilt with respect to the support surface: when the moveable component is off, the software code prevents the moveable component from turning on, and when the moveable component is on, the software code performs one of (a) turning off the moveable component, and (b) slowing down a regular rate of motion of the moveable component. When the tilt sensor is not sensing the tilt with respect to the support surface, the software code permits the moveable component to be turned on and have the regular rate of motion.

Abstract: A method and associated computer program product and system are disclosed. The method comprises, while a battery-operated vehicle is not being charged by a power supply, receiving a first input at a user interface displayed on a computing device. The method further comprises, responsive to the first input, wirelessly transmitting a first control signal to the battery-operated vehicle to control motive operation thereof. The method further comprises, responsive to receiving an indication that the battery-operated vehicle is being charged by the power supply, displaying one or more tasks to be completed using the user interface. The method further comprises receiving a second input at the user interface while the one or more tasks are displayed, and responsive to the second input, wirelessly transmitting a second control signal to operate one or more output devices of the battery-operated vehicle.

Abstract: According to one implementation, a stereoscopic image display system includes a computing platform having one or more hardware processor(s), a system memory storing a software code, an autostereoscopic display, and a user tracking unit controlled by the hardware processor(s). The hardware processor(s) execute the software code to utilize the user tracking unit to detect a left eye location and a right eye location of a user of the stereoscopic image display system, and to determine a left eye image and a right eye image corresponding to an output image of a content being played out by the stereoscopic image display system based on the respective left eye location and right eye location of the user. The hardware processor(s) further execute the software code to render the left eye image and the right eye image using the autostereoscopic display to generate a three-dimensional (3D) image of the output image.

Abstract: Systems and methods control sounds produced by a remote-controlled vehicle during operation of the remote-controlled vehicle are described herein. One or more components of the remote-controlled vehicle may be controlled and/or manipulated so that the remote-controlled vehicle produces sounds during operation that match a predetermined set of sounds. The control and/or manipulation of the one or more components of the remote-controlled vehicle may be effectuated without alternating a path of the remote-controlled vehicle.

Abstract: According to one implementation, a stereoscopic image display system includes a computing platform having one or more hardware processor(s), a system memory storing a software code, an autostereoscopic display, and a user tracking unit controlled by the hardware processor(s). The hardware processor(s) execute the software code to utilize the user tracking unit to detect a left eye location and a right eye location of a user of the stereoscopic image display system, and to determine a left eye image and a right eye image corresponding to an output image of a content being played out by the stereoscopic image display system based on the respective left eye location and right eye location of the user. The hardware processor(s) further execute the software code to render the left eye image and the right eye image using the autostereoscopic display to generate a three-dimensional (3D) image of the output image.

Abstract: According to one implementation, a communication system includes a computing platform having one or more hardware processor(s) and a system memory storing a software code, as well as an image capture device, a transceiver, and a display including one or more display screen(s) controlled by the hardware processor(s). The communication system also includes a base including a motor coupled to a rotor for rotating the display. The hardware processor(s) is/are configured to execute the software code to receive audio-visual data including image data corresponding to a remote venue and render the image data on the display screen(s) while spinning the display to generate a floating image of the remote venue. The hardware processor(s) is/are further configured to execute the software code to, concurrently with spinning the display, obtain local image data of a local venue and transmit local audio-visual data including the local image data to the remote venue.

Abstract: A method and associated computer program product and system are disclosed. The method comprises, while a battery-operated vehicle is not being charged by a power supply, receiving a first input at a user interface displayed on a computing device. The method further comprises, responsive to the first input, wirelessly transmitting a first control signal to the battery-operated vehicle to control motive operation thereof. The method further comprises, responsive to receiving an indication that the battery-operated vehicle is being charged by the power supply, displaying one or more tasks to be completed using the user interface. The method further comprises receiving a second input at the user interface while the one or more tasks are displayed, and responsive to the second input, wirelessly transmitting a second control signal to operate one or more output devices of the battery-operated vehicle.

Abstract: This disclosure presents systems and methods to provide a shared augmented reality experience across multiple presentation devices based on detection of one or more extraterrestrial bodies. A presentation device may be configured to detect presence of an extraterrestrial body. The presentation device may obtain resource information corresponding to the extraterrestrial body. The resource information may specify information specific to the extraterrestrial body including a location of the extraterrestrial body. The presentation device may generate an image of a virtual object. The image may be presented so that the virtual object may be perceived as being present at the location of the extraterrestrial body. The virtual object may augment the appearance of the extraterrestrial body. Gameplay may be carried out utilizing the virtual object.

Abstract: An interactive autonomous robot is configured for deployment within a social environment. The disclosed robot includes a show subsystem configured to select between different in-character behaviors depending on robot status, thereby allowing the robot to appear in-character despite technical failures. The disclosed robot further includes a safety subsystem configured to intervene with in-character behavior when necessary to enforce safety protocols. The disclosed robot is also configured with a social subsystem that interprets social behaviors of humans and then initiates specific behavior sequences in response.

Abstract: Systems and methods of simulating first-person control of remoted-controlled vehicles are described herein. The system may include one or more of a remote-controlled (RC) vehicle, a display interface, an input interface, and/or other components. The RC vehicle may have an image capturing device configured to capture in-flight images. View information representing the captured images may presented on a display worn and/or otherwise accessible to user. The input interface may allow the user to provide control inputs for dictating a path of the RC vehicle. Augmented reality graphics may be overlaid on the view information presented to the user to facilitate gameplay and/or otherwise enhance a user's experience.

Abstract: Systems, methods and articles of manufacture for synchronized robot orientation are described herein. A magnetometer, gyroscope, and accelerometer in a remotely controlled device are used to determine a current orientation of that device, and a command with a specified orientation or location are set to several such devices. The remotely controlled devices self-align based on the specified orientation/location, and when in position, receive swarm commands to perform actions as a group of devices in coordination with one another.

Abstract: Embodiments provide for autonomous drone play and directional alignment by in response to receiving a command for a remotely controlled device to perform a behavior, monitoring a first series of actions performed by the remotely controlled device that comprise the behavior; receiving feedback related to how the remotely controlled device performs the behavior, wherein the feedback is received from at least one of a user, a second device, and environmental sensors; updating, according to the feedback, a machine learning model used by the remotely controlled device to produce a second, different series of actions to perform the behavior; and in response to receiving a subsequent command to perform the behavior, instructing the remotely controlled device to perform the second series of actions.

Abstract: Systems and methods of simulating first-person control of remoted-controlled vehicles are described herein. The system may include one or more of a remote-controlled (RC) vehicle, a display interface, an input interface, and/or other components. The RC vehicle may have an image capturing device configured to capture in-flight images. View information representing the captured images may presented on a display worn and/or otherwise accessible to user. The input interface may allow the user to provide control inputs for dictating a path of the RC vehicle. Augmented reality graphics may be overlaid on the view information presented to the user to facilitate gameplay and/or otherwise enhance a user's experience.

Abstract: Systems and methods of simulating first-person control of remoted-controlled vehicles are described herein. The system may include one or more of a remote-controlled (RC) vehicle, a display interface, an input interface, and/or other components. The RC vehicle may have an image capturing device configured to capture in-flight images. View information representing the captured images may presented on a display worn and/or otherwise accessible to user. The input interface may allow the user to provide control inputs for dictating a path of the RC vehicle. Augmented reality graphics may be overlaid on the view information presented to the user to facilitate gameplay and/or otherwise enhance a user's experience.

Abstract: A system for flock-based control of a plurality of unmanned aerial vehicles (UAVs). The system includes UAVs each including a processor executing a local control module and memory accessible by the processor for use by the local control module. The system includes a ground station system with a processor executing a fleet manager module and with memory storing a different flight plan for each of the UAVs. The flight plans are stored on the UAVs, and, during flight operations, each of the local control modules independently controls the corresponding UAV to execute its flight plan without ongoing control from the fleet manager module. The fleet manager module is operable to initiate flight operations by concurrently triggering initiation of the flight plans by the multiple UAVs. Further, the local control modules monitor front and back end communication channels and, when a channel is lost, operate the UAV in a safe mode.

Abstract: A discharge platform comprises an air propulsion mechanism that propels the discharge platform through the air. The discharge platform also comprises a special effect storage device that stores a special effect and is operably connected to the discharge platform. Further, the discharge platform comprises a processor. In addition, the discharge platform comprises an air delivery special effect mechanism that discharges a special effect from the special effect storage device toward a destination after receiving an instruction from the processor and during propulsion of the discharge platform through the air by the air propulsion mechanism.

Abstract: Systems and methods of simulating first-person control of remoted-controlled vehicles are described herein. The system may include one or more of a remote-controlled (RC) vehicle, a display interface, an input interface, and/or other components. The RC vehicle may have an image capturing device configured to capture in-flight images. View information representing the captured images may presented on a display worn and/or otherwise accessible to user. The input interface may allow the user to provide control inputs for dictating a path of the RC vehicle. Augmented reality graphics may be overlaid on the view information presented to the user to facilitate gameplay and/or otherwise enhance a user's experience.

Abstract: A method for locating markers in an image captured by a mobile device moving about an operating space. The method includes preprocessing an image to generate a set of image data, locating fixed features of markers by tracing edges of the fixed features, and extracting variable data payloads of each of the markers associated with the located fixed features. The fixed features of each of the markers may include a pair of parallel lines extending along opposite sides of a data area containing the variable data payload, and each of the lines extends a distance beyond each exposed end of the data area to avoid missing data when markers are not arranged orthogonally to the scan direction. The preprocessing involves rotating or skewing the image to provide rotated or skewed versions of the image to facilitate locating markers regardless of their angular orientation in the image.