The present invention provides systems, methods, and devices related to target tracking by UAVs. The UAV may be configured to receive target information from a control terminal related to a target to be tracked by an imaging device coupled to the UAV. The target information may be used by the UAV to automatically track the target so as to maintain predetermined position and/or size of the target within one or more images captured by the imaging device. The control terminal may be configured to display images from the imaging device as well as allowing user input related to the target information.

A dynamic image masking system for providing a filtered autonomous remote sensing image through a dynamic image masking process is provided. The dynamic image masking system has a remote sensing platform and an imaging system associated with the remote sensing platform. The imaging system has an optical system and an image sensing system. The dynamic image masking system further has a multi-level security system associated with the imaging system and one or more image alteration locations located in the imaging system and the multi-level security system, wherein alteration of one or more images takes place via the dynamic image masking process. The dynamic image masking system further has a computer system associated with the imaging system. The computer system has a gatekeeper algorithm configured to send gatekeeper commands to one or more controllers that control the one or more image alteration locations through the dynamic image masking process.

Systems, methods, and devices are provided for providing flight response to flight-restricted regions. The location of an unmanned aerial vehicle (UAV) may be compared with a location of a flight-restricted region. If needed a flight-response measure may be taken by the UAV to prevent the UAV from flying in a no-fly zone. Different flight-response measures may be taken based on the distance between the UAV and the flight-restricted region and the rules of a jurisdiction within which the UAV falls.

A system for providing drone piggybacking on vehicles is disclosed. In particular, the system may enable drones or other unmanned mobile connected devices to piggyback onto various types of hosts, such as vehicles, in a symbiotic fashion. Through the symbiotic relationship created between the drones and hosts, the drones may utilize the hosts as a means for transport, such as while delivering a good to an intended destination, and the hosts may receive certain incentives in exchange for transporting the drones. Drones may be paired with hosts based on any number of factors, such as whether the host is traveling on a route that corresponds with reaching the intended destination, whether the host is capable of recharging the drone, and whether the drone has sufficient power to reach the intended destination. By enabling drones to piggyback with hosts, the required traveling range for a drone may be reduced.

A diversity receiver synchronizes and mixes multiple input signals. In one embodiment, the receiver demodulates the multiple input signals prior to synchronizing, converts the demodulated multiple input signals from analog signals to digital signals, synchronizes the demodulated digital signals, converts the synchronized demodulated digital signals to analog signals and mixes the synchronized demodulated analog signals based on a characteristic of the input signals existing prior to the demodulating.

An automated warehousing system for use in a warehouse having a storage racks includes drawers partitioned into multiple compartments to contain different parcels, the drawers being at designated locations of individual cells in the storage racks and adapted to be opened and closed. The system also has a plurality of drones configured to identify a designated one of the drawers at a designated location and a designated one compartment of the designated one drawer. The drones have gripper heads translatable relative to opened drawers to retrieve parcels therefrom. The system further has a communication subsystem communicating with the drones to control their flying and also to control their gripper heads relative to opened drawers and communicating with individual cells for opening and closing drawers as drones approach and depart the selected individual cells.

Embodiments of the present invention provide an alternative distributed airborne transportation system. In some embodiments, a method for distributed airborne transportation includes: providing an airborne vehicle with a wing and a wing span, having capacity to carry one or more of passengers or cargo; landing of the airborne vehicle near one or more of passengers or cargo and loading at least one of passengers or cargo; taking-off and determining a flight direction for the airborne vehicle; locating at least one other airborne vehicle, which has substantially the same flight direction; and joining at least one other airborne vehicle in flight formation and forming a fleet, in which airborne vehicles fly with the same speed and direction and in which adjacent airborne vehicles are separated by distance of less than 100 wing spans.

Methods, systems, and apparatus, including computer programs encoded on computer storage media, for ground control point assignment and determination. One of the methods includes receiving information describing a flight plan for the UAV to implement, the flight plan identifying one or more waypoints associated with geographic locations assigned as ground control points. A first waypoint identified in the flight plan is traveled to, and an action to designate a surface at the associated geographic location is designated as a ground control point. Location information associated with the designated surface is stored. The stored location information is provided to an outside system for storage.

An emergency unmanned aerial vehicle (UAV) and a method for employing a UAV. The method includes storing a digital elevation model (DEM) and associated data including locations of communication networks, updating the locations of communication networks in the associated data via a wireless transceiver, and storing position information determined by a global navigation satellite system (GNSS) receiver. The method includes detecting a predetermined condition using electronic sensors, determining whether the UAV is within a communications range of any communication network via the wireless transceiver, and determining a path to a communication network using the DEM and the associated data. The method also includes causing the UAV to become airborne and fly along the path, and transmitting a distress message via the wireless transceiver to the communication network, the distress message including position information corresponding to a location where the UAV detected the predetermined condition.

An Unmanned Aerial System configured to receive a request from a user and fulfill that request using an Unmanned Aerial Vehicle. The Unmanned Aerial System selects a distribution center that is within range of the user, and deploys a suitable Unmanned Aerial Vehicle to fulfill the request from that distribution center. The Unmanned Aerial System is configured to provide real-time information about the flight route to the Unmanned Aerial Vehicle during its flight, and the Unmanned Aerial Vehicle is configured to dynamically update its mission based on information received from the Unmanned Aerial System.