Abstract: Some embodiments are directed to an unmanned vehicle for transmitting signals. The unmanned vehicle includes a transmitting unit that is configured to transmit a signal towards an object. The unmanned vehicle also includes a control unit that is in communication with at least one companion unmanned vehicle. The control unit is configured to determine a position of the at least one companion unmanned vehicle relative to the unmanned vehicle. The control unit is further configured to control the transmitting element based on at least the position of the at least one unmanned vehicle such that the transmitting element forms a phased-array transmitter with a transmitting element of the at least one companion unnamed vehicle, the phased-array transmitter emitting a transmission beam in a predetermined direction.

Abstract: Some embodiments are directed to an unmanned vehicle. The unmanned vehicle can include a memory unit that is configured to store a planned path of the unmanned vehicle. The unmanned vehicle can also include a position unit that is configured to determine a current position of the unmanned vehicle, the position unit further configured to determine a planned position of the unmanned vehicle based on the planned path data stored in the memory unit. The unmanned vehicle can further include a control unit disposed in communication with the position unit, the control unit configured to determine a deviation based on the planned position and the current position of the unmanned vehicle, and control a movement of the unmanned vehicle such that the unmanned vehicle moves along the planned path if the deviation is less than a predetermined threshold.

Abstract: Some embodiments are directed to an unmanned vehicle for use with a companion unmanned vehicle. The unmanned vehicle includes a location unit that is configured to determine a current position of the unmanned vehicle. The unmanned vehicle includes a path planning unit that generates a planned path. The unmanned vehicle receives a planned path of the companion unmanned vehicle and a current position of the companion unmanned vehicle. The unmanned vehicle includes a position unit that is configured to determine a relative position between the unmanned vehicle and the companion unmanned vehicle based on at least the planned paths and the current positions of the unmanned vehicle and the companion unmanned vehicle. The unmanned vehicle also includes a control unit that is configured to control a movement of the unmanned vehicle based on at least the relative position between the unmanned vehicle and the companion unmanned vehicle.

Abstract: Some embodiments are directed to an unmanned vehicle for use with a companion unmanned vehicle. The unmanned vehicle includes a position unit that is configured to determine a current position of the unmanned vehicle. The unmanned vehicle includes a memory unit that is configured to store a planned path of the unmanned vehicle. The unmanned vehicle includes a control unit that is configured to determine that the unmanned vehicle is off-course based on the current position of the unmanned vehicle and the planned path assigned to the unmanned vehicle, generate a delay and a corrected path for the unmanned vehicle, and communicate the delay and the corrected path to the companion unmanned vehicle. The control unit is further configured to control a movement of the unmanned vehicle along the corrected path after the delay.

Abstract: An unmanned vehicle for use with an entity physically spaced from the unmanned vehicle, the unmanned vehicle having objective parameters corresponding to controlled parameters of the entity. The unmanned vehicle comprises a transceiver that is configured to wirelessly receive an input signal from the entity, wherein the input signal is indicative of the controlled parameters of the entity. The unmanned vehicle further comprises a Phase-Locked Loop (PLL) circuit that is configured to generate a command signal based on a phase of the input signal and a phase of a reference signal, wherein the reference signal is indicative of the objective parameters of the unmanned vehicle. The transceiver is further configured to wirelessly transmit the command signal to the entity such that the entity controls the controlled parameters of the entity based on the command signal.

Abstract: Some embodiments are directed to an unmanned vehicle for transmitting signals. The unmanned vehicle includes a transmitting unit that is configured to transmit a signal towards an object. The unmanned vehicle also includes a control unit that is in communication with at least one companion unmanned vehicle. The control unit is configured to determine a position of the at least one companion unmanned vehicle relative to the unmanned vehicle. The control unit is further configured to control the transmitting element based on at least the position of the at least one unmanned vehicle such that the transmitting element forms a phased-array transmitter with a transmitting element of the at least one companion unnamed vehicle, the phased-array transmitter emitting a transmission beam in a predetermined direction.

Abstract: The disclosed subject matter relates to methods and apparatus facilitating assessments of structural and electronic features, parameters, characteristics or any combination thereof using one or more unmanned autonomous vehicles. In some embodiments, an unmanned vehicle may be configured to monitor one or both of the structural and electrical characteristics of an object, and can also include cooperative behavior between two or more unmanned vehicles to test electrical communication in a directional fashion.

Abstract: A non-transitory processor-readable medium storing code causes a processor at a first vehicle (e.g., a first autonomous vehicle) to generate a first planned path based on a current position of the first vehicle and a mission requirement assigned to the first vehicle. A first planned path associated with a second vehicle (e.g., a second autonomous vehicle), which is based on a current position of the second vehicle and a mission requirement assigned to the second vehicle, is received at the first vehicle. After the first planned path associated with the second vehicle is received, a second planned path is generated based on the first planned path associated with the second vehicle and at least one of the mission requirement assigned to the first vehicle or the first planned path of the first vehicle. The second planned path of the first vehicle is transmitted to the second vehicle.

Abstract: A non-transitory processor-readable medium storing code causes a processor at a first vehicle (e.g., a first autonomous vehicle) to generate a first planned path based on a current position of the first vehicle and a mission requirement assigned to the first vehicle. A first planned path associated with a second vehicle (e.g., a second autonomous vehicle), which is based on a current position of the second vehicle and a mission requirement assigned to the second vehicle, is received at the first vehicle. After the first planned path associated with the second vehicle is received, a second planned path is generated based on the first planned path associated with the second vehicle and at least one of the mission requirement assigned to the first vehicle or the first planned path of the first vehicle. The second planned path of the first vehicle is transmitted to the second vehicle.

Abstract: A non-transitory processor-readable medium storing code causes a processor at a first vehicle (e.g., a first autonomous vehicle) to generate a first planned path based on a current position of the first vehicle and a mission requirement assigned to the first vehicle. A first planned path associated with a second vehicle (e.g., a second autonomous vehicle), which is based on a current position of the second vehicle and a mission requirement assigned to the second vehicle, is received at the first vehicle. After the first planned path associated with the second vehicle is received, a second planned path is generated based on the first planned path associated with the second vehicle and at least one of the mission requirement assigned to the first vehicle or the first planned path of the first vehicle. The second planned path of the first vehicle is transmitted to the second vehicle.

Abstract: A non-transitory processor-readable medium storing code causes a processor at a first vehicle (e.g., a first autonomous vehicle) to generate a first planned path based on a current position of the first vehicle and a mission requirement assigned to the first vehicle. A first planned path associated with a second vehicle (e.g., a second autonomous vehicle), which is based on a current position of the second vehicle and a mission requirement assigned to the second vehicle, is received at the first vehicle. After the first planned path associated with the second vehicle is received, a second planned path is generated based on the first planned path associated with the second vehicle and at least one of the mission requirement assigned to the first vehicle or the first planned path of the first vehicle. The second planned path of the first vehicle is transmitted to the second vehicle.

Abstract: A method for coordinating the paths of multiple autonomous vehicles and a vehicle configured to coordinate its path with the path(s) of other vehicles so as to enhance cooperation between the vehicles. The method also enables the vehicles to perform their respective missions more efficiently. The method is applicable to any system in which multiple autonomous vehicles may need to coordinate their paths with each other.

Abstract: A non-transitory processor-readable medium storing code causes a processor at a first vehicle (e.g., a first autonomous vehicle) to generate a first planned path based on a current position of the first vehicle and a mission requirement assigned to the first vehicle. A first planned path associated with a second vehicle (e.g., a second autonomous vehicle), which is based on a current position of the second vehicle and a mission requirement assigned to the second vehicle, is received at the first vehicle. After the first planned path associated with the second vehicle is received, a second planned path is generated based on the first planned path associated with the second vehicle and at least one of the mission requirement assigned to the first vehicle or the first planned path of the first vehicle. The second planned path of the first vehicle is transmitted to the second vehicle.