The invention is intended for the organization of an automated process for spraying of liquid means of chemical treatment from unmanned vehicles, for example, in precise farming systems. The invention provides the use of a replaceable, marked and hermetically sealed liquid subsystem with integrated pumping chambers in a spraying device together with an integrated self-diagnosis system allowing to ensure personnel safety and the accounting of the resources of main components of the spraying device. All this in combination enables to create fully automated spraying systems.

A rechargeable drone apparatus or arrangement is provided. The rechargeable drone device includes a series of sensors configured to receive information about a user and transmit the information to a computing system configured to assess the information collected from the drone device and a set of securable compartments configured to maintain samples or medications, wherein the series of securable compartments are configured to be openable by an approved individual.

A vehicle including: a first bay configured to accommodate a ground-based moving body; a second bay configured to accommodate a flying moving body; a cargo hold connected to both the first bay and the second bay, and configured to store a package to be moved to either the ground-based moving body or the flying moving body; a first memory; and a first processor connected to the first memory, the first processor being configured to select whether to move the package in the cargo hold to the ground-based moving body or the flying moving body.

A method for deploying a drone including transporting a drone from a first location to a second location with a vehicle and supplying electricity from the vehicle to the drone while the drone is being transported. A launch command can be initiated from within the vehicle to direct the drone to ascend and hover above the vehicle. The drone can be transported in a drone port mounted to the vehicle.

Disclosed are systems, methods and computer program products for performing data backup using an unmanned aerial vehicle (UAV). An example method includes in response to detecting a data backup request from a user device, determining a geographic location of the user device and dispatching the UAV to the geographic location; controlling the UAV to obtain user data from the user device; and controlling the UAV to navigate to a data center to back up the obtained user data onto a cloud storage.

A portable case for an unmanned aerial vehicle (UAV) and a system including a portable case for UAV and an adapter for coupling the portable case to a vehicle are disclosed. An example system may include an exterior attachment disposed on an exterior of a vehicle, an adapter configured to couple a portable case for an UAV to the exterior attachment, and a moveable cover connected to the vehicle and configured to cover the portable case when the portable case is coupled to the vehicle. An example portable case may comprise a landing pad for the UAV, a bottom portion having the landing pad and configured to connect to the exterior attachment via the adapter, and a removable upper portion configured to be connected to the bottom portion when the bottom portion is disconnected from the at least one exterior attachment.

The invention concerns an airborne device comprising at least three supporting wings and a linking device, the wings being linked to each other by first flexible cables, each wing being further linked to the linking device by a second flexible cable, the linking device being linked to a third flexible cable intended to be linked to a base, the first second, and third cables being tensioned when the airborne device is carried in the wind.

The invention is a modular vehicle having an air vehicle that can be coupled to cargo containers, land vehicles, sea vehicles, medical transport modules, etc. In one embodiment the air vehicle has a plurality of propellers positioned around a main airframe, which can provide vertical thrust and/or horizontal thrust depending on the configuration. One or more of the propellers may be configured to tilt forward, backward, and/or side-to-side with respect to the airframe.

A transport system includes an unmanned aircraft including an article holding section; and a transport vehicle that includes at least one aircraft holding section configured to hold the unmanned aircraft, and that is configured to travel along a predetermined travel path, wherein the at least one aircraft holding section 44 is further configured to (i) hold the unmanned aircraft in either one of an article holding state in which the unmanned aircraft is holding the article W using the article holding section, and an article non-holding state in which the unmanned aircraft is not holding the article W using the article holding section, and (ii) allow the unmanned aircraft in either one of the article holding state and the article non-holding state to take off and land.

A transport system includes an unmanned aircraft including an article holding section; and a transport vehicle that includes at least one aircraft holding section configured to hold the unmanned aircraft, and that is configured to travel along a predetermined travel path, wherein the at least one aircraft holding section 44 is further configured to (i) hold the unmanned aircraft in either one of an article holding state in which the unmanned aircraft is holding the article W using the article holding section, and an article non-holding state in which the unmanned aircraft is not holding the article W using the article holding section, and (ii) allow the unmanned aircraft in either one of the article holding state and the article non-holding state to take off and land.