A controller monitors for an activation condition through a monitoring interface of a wearable aerial device. In response to detecting the activation condition through the monitoring interface, the controller triggers the wearable aerial device to release from an aesthetic attachment proximate to a user and hover a distance above the user of a height above a selected height threshold. The controller analyzes a recording of content by the wearable aerial device to assess a particular threat level associated with the content from among multiple threat levels. The controller, in response to the particular threat level exceeding a threat threshold, automatically sends a communication to one or more emergency contacts.

Vehicles such as unmanned air vehicles that are capable of movement from an open, flight configuration to an enclosed configuration in which all major flight components can be protected by an outer shell are disclosed. In the enclosed configuration, the vehicles can take on standard geometric shapes such as a rectangular prism, sphere, cylinder, or another shape, so as to not be recognizable as an unmanned air vehicle. Embodiments of vehicles can also include interchangeable and/or wireless motor arms, motor arms which are electrically connected to the remainder of the vehicle only when in an open configuration, remote controllers removably attached to the remainder of the vehicle, and clip or other attachment mechanisms for attachment to objects such as backpacks.

Provided an information processing device that is capable of switching between a state in which a device is carried and a state in which the device is not carried in a more suitable form in accordance with a state or situation in which the device is used. The information processing device includes an acquisition unit that acquires information on a user and a controller that executes a control process for moving a device that can be carried by the user so that the device changes between a carry state in which the device is carried by the user and a non-carry state in which the device is not carried by the user on the basis of the information on the user.

A virtual reality system includes a drone including a rotor, a display, an audio speaker, a body harness having adjustable straps, and one or more processors in operative communication with the display, the audio speaker, and the drone. The drone may be fixed to the body harness. The one or more processors may be configured to issue audio-visual content to the display and audio speaker and control the rotor based on the issued audio-visual content.

A smart belt system worn by a person comprising an elongated belt configured for removably coupling a plurality of devices, a GPS component coupled to the belt configured to track the geo-location and movement of the belt, a microprocessor coupled to the belt, logic instructions executing by the microprocessor configured to monitor and regulate the activities of the plurality of devices and geo-location and movement data generated by the GPS component, a memory component configured for storing the logic instructions and accessible by the microprocessor, a wireless data communications system coupled to the belt configured to wirelessly communicate with an external data communications system and the microprocessor, a power and data bus disposed within the belt and communicatively coupled to at least one of the plurality of devices, GPS component, microprocessor, memory, wireless data communications systems, and data storage component; and a data storage component coupled to the belt and accessible by the microprocessor for storing activity data of at least one of the plurality of devices and the geo-location and movement data of the belt generated by the GPS component.

In an aspect, in general, a spooling apparatus includes a filament feeding mechanism for deploying and retracting filament from the spooling apparatus to an aerial vehicle, an exit geometry sensor for sensing an exit geometry of the filament from the spooling apparatus, and a controller for controlling the feeding mechanism to feed and retract the filament based on the exit geometry.

Provided is an information processing device that is capable of switching between a state in which a device is carried and a state in which the device is not carried in a more suitable form in accordance with a state or situation in which the device is used. The information processing device includes an acquisition unit that acquires information on a user and a controller that executes a control process for moving a device that can be carried by the user so that the device changes between a carry state in which the device is carried by the user and a non-carry state in which the device is not carried by the user on the basis of the information on the user.

A UAV landing platform having movable covers to securely store/maintain/charge a UAV. The UAV may be launched from the landing platform, and the landing platform can have visual indicators to guide the landing of the UAV back onto the landing platform. There can be an optional mechanism to self-adjust/self-level the landing surface such that a UAV can safely land onto the landing platform even when the landing platform is on a traveling vehicle.

The present technology is directed to a remotely controlled aircraft that can be transported without the risk of damaging certain components, such as the arms and/or propellers. In one non-limiting example, the remotely controlled aircraft technology described herein provides a housing that allows the arms of the remotely controlled aircraft to extend and/or retract through openings in the housing. When retracted, the arms and propellers are protected within an area of the structure of the housing, and when extended, the arms and propellers are operable to make the remotely controlled aircraft fly.

The disclosed inventions include personal Unmanned Aerial Vehicles (UAV's) and UAV universal docking ports docking ports to be incorporated into and/or attached to headwear, including helmets, hard hats and hats and face masks, as well as footwear including boots and shoes, clothing and outerwear, devices, gear and equipment, land, air, water and space vehicles, buildings, wireless towers and other mobile or stationary objects and surfaces referred to collectively as docking stations. A docking station may have one or more docking ports for docking, networking and charging or refueling compact personal UAVs, and for providing data communications between said UAVs and other electronic devices that remain with the person while the UAV is in flight or driving or landed on terrain. Said docking ports may also incorporate wireless power transmission for remote wireless charging of one or more UAV's. Supplemental power for recharging said UAVs when docked may be supplied by integrated battery(s) in said docking port or me be provided directly from the docking station or other connected power source.