A model vehicle with body mount components are provided. A tongue member attached to a model vehicle body with a first and second tongue member is configured to engage a first securing member attached to a model vehicle chassis. A top surface of the second tongue member draws the model vehicle body towards the model vehicle chassis when the second tongue member engages the first securing member. A lever member with a lever handle, jaw clamp, and a lever pivot is configured to pivot between an engage and an unengaged position. The jaw clamp engages with a second securing member in the engaged position. The lever member further contains a retaining mechanism that is configured to rotate between a retained and unretained position. The retaining mechanism inhibits the lever handle from moving from the engaged to the unengaged position when the retaining mechanism is in the retained position.

A method for controlling a movable object includes acquiring one or more images captured by an imaging device borne by the movable object and at least partially blocked by an obstructive object attached to the movable object, detecting at least portion of the obstructive object projected in the one or more images, and processing the one or more images with the projected obstructive object to assist an operation of the movable object.

The present embodiments disclose a torque dependent and resonant operating thrust-generating rotor assembly including a cyclic pitch control system for controlling tilting moments about a longitudinal rotor blade axis of one or more rotor blades, in order to control the pitch angle of the rotor blades and thereby also the horizontal movements of a helicopter vehicle or a rotary wing aircraft. A rotor torque assembly of the rotor assembly is further configured to operate in resonance, thereby providing a resonant gain effecting a rotational offset in relation to changes in torque generated by the motor.

The present invention relates to an object controller capable of controlling a movement and a rotation of an object. The present invention provides an object controller capable of controlling a motion of an object, the object controller including: a main body; an operating unit which is in non-contact with the main body; and a control unit which controls a motion of the object based on a relative position of the operating unit to the main body.

Multi-rotor aerial vehicle (1, 1, 1, 1, 1, 1, 1) comprising, at least a first, second and third rotor 10, 20, 30, each rotatable by a dedicated first second and third hydraulic motor 11, 21, 31, a power unit 2, at least a first, second and third hydraulic pump 12, 22, 32 dedicated to the respective first, second and third hydraulic motor 11, 21, 31, wherein each hydraulic pump 12, 22, 32 is arranged to provide pressurized fluid to each hydraulic motor 11, 21, 31 for powering the hydraulic motor 11, 21, 31 and thereby rotating the respective rotor 10, 20, 30, a control unit 6 for controlling the operation of the multi-rotor aerial vehicle (1, 1, 1, 1, 1, 1, 1), wherein the control of the multi-rotor aerial vehicle (1, 1, 1, 1, 1, 1, 1) is arranged to be performed by altering the flow of pressurized fluid distributed to each respective hydraulic motor 11, 21, 31, wherein, wherein the flow of pressurized fluid provided to each hydraulic motor 11, 21, 31 is individually controllable by means of at least one control valve 13, 23, 33 configured to control the flow of pressurized fluid from each hydraulic pump 12, 22, 32 to its dedicated hydraulic motor 11, 21, 31.

A system and method of competitively gaming in a mixed reality with multiple players provides a facility in which various types of drone/RC vehicle, including, but not limited to, quadcopters, submarines, tanks, radio-controlled vehicles, and more, may be stored, maintained, and deployed. Appropriate environments are provided and changed in order to provide variety to the gamers. Users enter a pod equipped with virtual reality headgear and several controls befitting the drone/RC vehicle type or game type being played. The virtual reality headgear enables users to control the drone/RC vehicle from a first-person perspective, utilizing cameras strategically dispersed throughout the drone/RC vehicle. Between uses, drones/RC vehicles are sent through automated maintenance, which allows for standard maintenance for functional units and automated part replacement as needed for damaged units. The automated maintenance allows for continuous play, as opposed to single unit aerial drone racing, in which drones generally require maintenance between uses.

The present invention relates to a device for supplying electrical power to a wired system for a drone (1). The device according to the invention includes at least one power converter (4) on the ground and one power converter (2) at the level of the drone (1), regulation at the level of the converter on the ground ensures that the output voltage of the power converter (4) on the ground increases when the output current of the power converter (4) on the ground increases. The method according to the invention is intended for all wired drones, the wire (3) of which is used to supply electrical power to the drone (1).

A Lynchpin structure may be combined with one or more additional Lynchpin structures to form a compound Lynchpin propulsion structure. Each Lynchpin structure may include six pentangular areas, and one or more of the pentangular areas may include a propulsion device. The propulsion may be used to propel the compound Lynchpin propulsion structure through or over various media, such as through air, across ground, on or underwater, or through or over other media. The propulsion may include avionic propulsion, ground propulsion, hydrodynamic propulsion, or other types of propulsion. A single type of propulsion device may be used within one or more of the pentangular areas, or diverse types of propulsion may be used to provide various navigational performance or multi-mode operation. Each propulsion device may also include a device to direct the propulsion, such as a single or multi-axis gimble or adjustable aerodynamic control surface.

A themed aerial vehicle entertainment system or platform useful for generating crowd-pleasing shows or displays through the use of dynamically-coordinated show systems. Instead of use of a fixed flight plan, the new entertainment platform is configured to include one or more UAVs that is enclosed within or supports thematic cladding such as the outer shell of a spacecraft or flying character, and the show is dynamically coordinated to present a cohesive performance. Onboard show effects provided by onboard or UAV supported show system components such as high brightness lights are dynamically adjusted in the new system/platform to ensure the best show appearance to the audience while providing safer operations. The dynamic adjustments may involve selecting or generating a second script or B show in a contingent manner based on the current location or timing of movement of the UAV along a flight plan.

A collapsible flying device is provided having a housing including first and second housing sections forming an enclosure, and a motorized assembly that includes a drive motor and a drive shaft driven by the drive motor. The drive shaft matingly receives the first housing section and is coupled to the second housing section, wherein operation of the drive motor drives the drive shaft to move the first housing section from a closed position adjacent the second housing section to an open position spaced from the second housing section. A rotor hub is rotatingly driven by the drive motor. At least two rotor blades are coupled thereto and positioned within the enclosure in a collapsed position when the first housing section is in the closed position, and extend beyond the enclosure in an expanded position when the first housing section is in the open position.