A vehicle includes a propulsion system using one or more impellers as opposed to propellers. The impellers impart circumferential and radial velocity components to the working fluid, which may be air or water. The air is deflected by counter-vortex chambers in a shroud to convert the circumferential and radial velocity to an axial velocity aligned with the axis of rotation of the impeller.

A quadrotor UAV including ruggedized, integral-battery, load-bearing body, two arms on the load-bearing body, each arm having two rotors, a control module mounted on the load-bearing body, a payload module mounted on the control module, and skids configured as landing gear. The two arms are replaceable with arms having wheels for ground vehicle use, with arms having floats and props for water-surface use, and with arms having pitch-controlled props for underwater use. The control module is configured to operate as an unmanned aerial vehicle, an unmanned ground vehicle, an unmanned (water) surface vehicle, and an unmanned underwater vehicle, depending on the type of arms that are attached.

A modular vehicle system includes at least one body module having at least one body connection interface, and a kit. The kit includes a plurality of utility modules including at least one first utility module (in the form of a fixed-wing utility module) and at least one second utility module (in the form of a rotor-wing utility module). Each first utility module includes at least one utility module connection interface in the form of a first utility module connection interface for coupling with the body connection interface. Each second utility module includes at least one utility module connection interface in the form of a second utility module connection interface, distinct from the first utility module connection interface, for coupling with the body connection interface. Each body connection interface is configured for selective reversible coupling at least with respect to any one of the utility module connection interfaces while concurrently excluding coupling of another utility module connection interface thereto, to provide an air vehicle.

Systems and associated methods for rapid integration and control of payloads carried by a multi-mode unmanned vehicle configured to accommodate a variety of payloads of varying size, shape, and interface and control characteristics. Mechanical, power, signal, and logical interfaces to a variety of payloads operate to enable environmental protection, efficient placement and connection to the vehicle, and control of those payloads in multiple environmental modes as well as operational modes (including in air, on the surface of water surface, and underwater).

A convertible multi-mode vehicle capable of motorized travel in the air, on land, on water, and under water. The multi-mode vehicle is capable of controlled aerial flight, movement on the ground in terrestrial environments, on an aquatic surface, as well as underwater by changing between the different modes. Pivoting propulsion motors enable a convertible configuration from one vehicle locomotion mode to another.

The present application discloses an apparatus capable of walking and flight. This apparatus includes a central section supported by a plurality of limbs, wherein a distal end of each of the plurality of limbs defines a contact surface. These limbs are configured to generate a walking-type motion in which the contact surfaces of the limbs cooperate with an environmental surface in a manner sufficient to propel the central section relative the environmental surface. The apparatus further includes a motor operably coupled to at least one limb of the plurality of limbs, wherein the motor is drivingly coupled to a propeller, and wherein the motor and propeller are configured to propel the central section in flight.

Disclosed are a wall-climbing aerial robot mechanism and a method of controlling the same. The method of controlling a wall-climbing aerial robot includes allowing the aerial robot to fly towards a structure, allowing the aerial robot to approach the structure and recognize a wall of the structure, allowing the aerial robot to calculate a trajectory for landing on the wall of the structure, approach the wall of the structure after taking an orientation, and be attached on the wall of the structure, and allowing the aerial robot to move along the wall of the structure to perform a task.

Transformable unmanned vehicles and related methods are disclosed. An example vehicle includes a body having, a first cap, a second cap spaced from the first cap, and a plurality of segments radially spaced relative to a longitudinal axis of the body. The segments are movable relative to the first cap and the second cap. The vehicle includes a payload supported by the first cap. An actuation system moves the segments relative to the first cap and the second cap to transform the body between a first configuration and a second configuration different than the first configuration.

A vehicle for aerial-aquatic locomotion is provided. The vehicle may include a propeller, an electric motor operably coupled to the propeller and configured to rotate the propeller, a maneuvering assembly configured to change an attitude and altitude of the vehicle, and a controller operably coupled to the electric motor and the maneuvering assembly. The controller may be configured to receive a command for the vehicle to exit a first medium and enter a second medium, compute or retrieve a hybrid trajectory, and control the electric motor and the maneuvering assembly to maneuver the vehicle in accordance with the hybrid trajectory.

The present application discloses an apparatus capable of walking and flight. This apparatus includes a central section supported by a plurality of limbs, wherein a distal end of each of the plurality of limbs defines a contact surface. These limbs are configured to generate a walking-type motion in which the contact surfaces of the limbs cooperate with an environmental surface in a manner sufficient to propel the central section relative the environmental surface. The apparatus further includes a motor operably coupled to at least one limb of the plurality of limbs, wherein the motor is drivingly coupled to a propeller, and wherein the motor and propeller are configured to propel the central section in flight.