Abstract: A distributed hardware system for unmanned vehicles is provided, comprising a plurality of electronic hardware modules in communication via a vehicle control network. Each module is enabled to: communicate with one another, issue requests for information from a central control module, and transmit data over the network in a common format to perform respective tasks; and at least one of: independently sense one or more of: a respective status of the distributed hardware system and at least one respective environmental parameter; and independently control the respective function of a vehicle. A portion of the modules can enabled to: be removed and inserted from the distributed hardware system as plug and play modules; and determine when at least one of the modules is removed/inserted from the distributed hardware system and transition to a corresponding state. The system also includes a power management system which includes capacity monitoring and hot-swap capabilities.

Abstract: A distributed hardware system for unmanned vehicles is provided, comprising a plurality of electronic hardware modules in communication via a vehicle control network. Each module is enabled to: communicate with one another, issue requests for information from a central control module, and transmit data over the network in a common format to perform respective tasks; and at least one of: independently sense one or more of: a respective status of the distributed hardware system and at least one respective environmental parameter; and independently control the respective function of a vehicle. A portion of the modules can enabled to: be removed and inserted from the distributed hardware system as plug and play modules; and determine when at least one of the modules is removed/inserted from the distributed hardware system and transition to a corresponding state. The system also includes a power management system which includes capacity monitoring and hot-swap capabilities.

Abstract: A method of remotely controlling an aerial vehicle within an environment, including providing a control station in communication with the aerial vehicle, providing a map of the environment, receiving target world coordinates for the aerial vehicle within the environment, determining a desired velocity vector to direct the aerial vehicle to the target world coordinates at a speed proportional to the distance between the aerial vehicle and the target world coordinates, and directing the aerial vehicle along the desired velocity vector until the aerial vehicle reaches the target world coordinates.

Abstract: An unmanned vehicle system containing one or more vehicles equipped with an autonomous control system. Each vehicle is of navigating on its own when provided with goals. A user is capable of sending and receiving goals from the autonomous control system via a communication link. A unified display interface displays information about the system and accepts commands from the user. The display interface in question is modeless and has a minimum of clutter and distractions. The form of this display interface is that of a set of screens, each of which is able to receive touch inputs from the user. The user is able to monitor and control individual vehicles or the entirety of the UVS solely through their use of a standard touchscreen with no additional peripherals.

Abstract: A method of remotely controlling an aerial vehicle within an environment, including providing a control station in communication with the aerial vehicle, providing a map of the environment, receiving target world coordinates for the aerial vehicle within the environment, determining a desired velocity vector to direct the aerial vehicle to the target world coordinates at a speed proportional to the distance between the aerial vehicle and the target world coordinates, and directing the aerial vehicle along the desired velocity vector until the aerial vehicle reaches the target world coordinates.