A propulsion system for an aerial vehicle having a wing structure operating in a wildfire environment, wherein the wing structure includes a drive extending through a top and a bottom surface of the wing structure and configured to provide a thrust through the top and bottom surface of the wing structure along a vertical axis of the aerial vehicle. The drive may be magnetohydrodynamic drive or an open Nacelle Fan assembly. The drive may be magnetohydrodynamic drive or an open Nacelle Fan assembly The Open Nacelle Propulsion Fan uses a drive mechanism with an induced magnetic field generated by an induction coil housed within the fan assembly open to the ambient environment, a counter-rotating fan assembly including a first fan rotating clockwise, and configured to adjust the pitch of the propulsion fan, thereby enabling the aerial vehicle's thrust to be vectored as determined by the command module.

A propulsion system for an aerial vehicle having a wing structure operating in a wildfire environment, wherein the wing structure includes a drive extending through a top and a bottom surface of the wing structure and configured to provide a thrust through the top and bottom surface of the wing structure along a vertical axis of the aerial vehicle. The drive may be magnetohydrodynamic drive or an open Nacelle Fan assembly. The drive may be magnetohydrodynamic drive or an open Nacelle Fan assembly The Open Nacelle Propulsion Fan uses a drive mechanism with an induced magnetic field generated by an induction coil housed within the fan assembly open to the ambient environment, a counter-rotating fan assembly including a first fan rotating clockwise, and configured to adjust the pitch of the propulsion fan, thereby enabling the aerial vehicle's thrust to be vectored as determined by the command module.

A multimodal propulsion system of a remotely operated, semi-autonomous, autonomous operated aerial vehicle of a fire-resistant aerial vehicle for suppressing widespread fires deploying hybrid convergent-divergent nozzle systems, electric fans, compressed air subsystems, individually or in combination, primarily powered by ambient air from the fire environment, providing thrust, lift, thrust and lift.

Low noise vertical take-off and landing (VTOL) unmanned air vehicle. A vertical take-off and landing unmanned vehicle which generates low levels of noise includes an ion thruster providing a thrust in a vertical direction, and a thrust vectoring system providing thrust in at least one of a forward, aft, left, and right direction, when the unmanned vehicle is in flight

Low noise vertical take-off and landing (VTOL) unmanned air vehicle. A vertical take-off and landing unmanned vehicle which generates low levels of noise includes an ion thruster providing a thrust in a vertical direction, and a thrust vectoring system providing thrust in at least one of a forward, aft, left, and right direction, when the unmanned vehicle is in flight

A differential thrust vectoring system includes a first thruster, a second thruster, a main actuator, and a trim actuator. The system is configured such that actuation of the main actuator causes rotation of the thrusters together about an axis, whereas actuation of the trim actuator causes relative rotation of the first and second thrusters about the axis.

An unmanned aerial vehicle is an unmanned aerial vehicle configured to fly in a closed space, which includes an airframe, a thrust generating means configured to generate a thrust for the airframe to fly in air, and a length measuring means mounted on the airframe. The length measuring means includes a transmission unit configured to transmit a measurement wave, a reception unit configured to receive reflected waves of the measurement wave, and a distance calculation unit configured to calculate a distance between the unmanned aerial vehicle and a stationary object present in the closed space based on the reflected waves of the measurement wave transmitted from the transmission unit which are received a plurality of times by the reception unit.

A propulsion assembly for an aircraft includes a nacelle having a rapid connection interface, at least one battery disposed within the nacelle, a speed controller coupled to the battery and a propulsion system coupled to the speed controller and the battery. The propulsion system includes an electric motor having an output drive and a rotor assembly having a plurality of rotor blades that are rotatable with the output drive of the electric motor in a rotational plane to generate thrust. The electric motor is operable to rotate responsive to power from the battery at a speed responsive to the speed controller. The rapid connection interface of the nacelle is couplable to a rapid connection interface of an airframe nacelle station to provide structural and electrical connections therebetween that are operable for rapid in-situ assembly.

An aircraft control system for an unmanned aircraft comprising a forward propulsion system comprising a forward thrust engine and a vertical propulsion system comprising a vertical thrust engine. The aircraft control system may include a controller comprising an input coupled to receive a velocity signal indicating a determined amount of forward velocity and being configured to generate a pitch angle command associated with the determined amount of forward velocity; a splitting block comprising an input to receive the pitch angle command and being configured to generate a second pitch angle command and a forward thrust engine throttle command based on a bounded pitch angle for the unmanned aircraft; and an output coupled to provide the second pitch angle command to the vertical propulsion system and the forward thrust engine throttle command to the forward propulsion system.

An aerial vehicle includes an airframe; vertical propulsion units, and a controller. The vertical propulsion units are mounted to the airframe and include propellers oriented to provide vertical propulsion to the aerial vehicle. The vertical propulsion units are physically organized in quadrants on the airframe with each of the quadrants including two or more of the vertical propulsion units. The controller is coupled to the vertical propulsion units to control operation of the vertical propulsion units. At least two of the vertical propulsion units in each of the quadrants are adapted to counter-rotate from each other during flight of the aerial vehicle.