An information processing device determines, based on location information of a plurality of delivery destinations for package delivery: one or a plurality of first delivery destinations for package delivery by a vehicle; and one or a plurality of second delivery destinations for package delivery by a drone mounted on the vehicle. In addition, the information processing device determines: a travel route including a route for the vehicle to perform package delivery to the one or plurality of first delivery destinations; a first point on the travel route for the drone to start flying from the vehicle to the one or plurality of second delivery destinations; and a second point on the travel route for the drone to return to the vehicle.

Landing pads for a drone. One of the landing pads can include a landing station configured to mount onto a non-horizontal surface; a landing area i) connected to the landing station and ii) with a first surface configured to receive a second surface of a landing gear of a drone; a fixed member i) connected to the landing station and that ii) includes a third surface near an end of the landing area and iii) is configured to contact an end of the landing gear of the drone; a moveable member i) connected to the landing station and ii) that is configured to a) move the landing gear across the first surface of the landing area and b) secure the landing gear of the drone substantially in place between the first surface of the landing area and the third surface of the fixed member.

The present invention relates to a mobile security robot equipped with a micro flight device, which uses a camera mounted on the mobile security robot to patrol a predetermined area by the mobile security robot capable of autonomous driving and to patrol an area where the mobile security robot cannot move by the mounted micro flight device. Accordingly, there is an advantage in that it can efficiently patrol a much wider area compared to the patrol using only the mobile security robot.

Systems and methods are described for a cyber-physical vehicle management system generated by an Integrated Secure Device Manager (ISDM) Authority configured to manage licensing and approval of Cyber-Physical Vehicle (CPV)s, a public/private key pair and a unique ID for the Authority, create a self-signed Authority token signed by the private key, send the Authority token to a plurality of ISDM Node device configured to verify Module device authenticity and in communication with the Authority, store, by each Node, the Authority token, and mark, by each Node, the Authority token as trusted.

A method and a system configured to execute the mentioned method is suggested, where the method is capturing media content associated with at least one object, using a plurality of media capturing devices, each carried by a mobile communication device, together forming a mobile media device. The method comprise: controlling each of the mobile media devices according to a respective, predefined role and role specific rules for mobile media device movements, while capturing media content, following the movement of the at least one determined object; acquiring sensor data, indicative of the mobile media device movements, from the mobile media devices, and updating the roles of the mobile media devices, based on the acquired sensor data.

A buoyant aerial vehicle includes: a balloon configured to store a gas; a payload coupled to the balloon; and a propulsion unit coupled to the payload by a tether. The propulsion unit includes: a fuselage having a substantially longitudinal shape, a first end, and a second end; a primary airfoil coupled to the fuselage; a secondary airfoil coupled to the fuselage at one of the first end or the second end; and a thrust generating device disposed at one of the first end or the second end and configured to move the propulsion unit relative to the payload along a propulsion flight path. The movement of the propulsion unit imparts movement of the buoyant aerial vehicle along a vehicle flight path.

Systems, methods, and computer-readable storage media for receiving, from an issuer, an electronic prescription for a patient, then fulfilling that prescription using a blockchain/distributed ledger verification system. The system receives multiple public keys, combines them, then performs a hash function (or other encryption) on that combination. The resulting output is then transmitted to a pharmacy for prescription fulfillment.

This disclosure describes systems and methods for a multipoint cable cam (MPCC) of an aerial vehicle. A method includes operations of receiving user input associated with a predetermined path and correlating the received user input with stored global positioning satellite (GPS) data to generate one or more virtual waypoints along the predetermined path. The method includes processing the one or more virtual waypoints to generate a spline-based flight path. The method may include storing the spline-based flight path and transmitting the spline-based flight path to the aerial vehicle.

Certain exemplary embodiments can provide an AirBox constructed to receive deliveries from a drone. The AirBox can comprise an automatically openable lid; and a wireless receiver that is constructed to receive data concerning a delivery from the drone. The automatically openable lid can open to receive the delivery from the drone.

Lock apparatus and related methods for use with drones are disclosed. A disclosed drone assembly includes a wing, a keel-beam, an adapter positioned on an end of the keel-beam, and a lock configured to receive the adapter. The lock includes a first lock portion coupled to the wing and a second lock portion rotatable relative to the first lock portion between a first position and a second position. The lock is configured to (a) couple the keel-beam to the wing when the second lock portion is in the second position and (b) decouple the keel-beam from the wing when the second lock portion is in the first position.