A tether compensated unmanned aerial vehicle (UAV) is described. In one embodiment, the UAV includes a winch with a tether to lower an item from the UAV for delivery, a flight controller to control a flight path of the UAV, a tether compensation mechanism through which the tether extends, at least one sensor to identify movement in the tether, and a tether response controller. Based on movement identified in the tether, the tether response controller may determine a complementary response and direct the tether compensation mechanism to brace the tether against the movement. Thus, the tether compensation mechanism may stabilize sway or movement in the tether by moving against the sway or movement, which may help prevent the tether from undesirable swinging when lowering the item from the UAV for delivery, for example, or at other times.

A VTOL (vertical take-off and landing) aerial flying vehicle comprising an inner frame, a gimbal system and an outer frame, the inner frame comprising a propulsion system and a control system. The propulsion system being able to generate a lift force. The control system being able to control the orientation of the inner frame. The gimbal system connecting the inner frame to the outer frame with at least two rotation axis allowing rotation freedom between the outer frame to rotate independently from the inner frame.

A VTOL (vertical take-off and landing) aerial flying vehicle comprising an inner frame, a gimbal system and an outer frame, the inner frame comprising a propulsion system and a control system. The propulsion system being able to generate a lift force. The control system being able to control the orientation of the inner frame. The gimbal system connecting the inner frame to the outer frame with at least two rotation axis allowing rotation freedom between the outer frame to rotate independently from the inner frame.

Load stability systems and methods for stabilizing swinging motions of suspended loads. The load stability systems include a fully automated, self-powered device that employs thrust to counteract and control lateral and rotational motion of an external load. The device is a temporary installment on the load, cable, or boom, and is agnostic to the platform from which it is suspended.

Load stability systems and methods for stabilizing swinging motions of suspended loads. The load stability systems include a fully automated, self-powered device that employs thrust to counteract and control lateral and rotational motion of an external load. The device is a temporary installment on the load, cable, or boom, and is agnostic to the platform from which it is suspended.

An electric vertical take-off and landing vehicle includes a fuselage containing an internal compartment which may be used to transport a person, animal, or object. The fuselage includes a canard located at a forward portion of the fuselage in front of the internal compartment. A pair of wings extend outward from the fuselage wherein each of the pair of wings contains a propulsion unit configured to provide thrust. It is desired that each propulsion unit is in fixed orientation to the fuselage and the pair of wings. A landing foot is also included and configured to rotate the fuselage into and out of a vertical orientation when on the ground. The internal compartment of the fuselage is configured to rotate to maintain an upright orientation as the fuselage is at its various orientations.

An electric vertical take-off and landing vehicle includes a fuselage containing an internal compartment which may be used to transport a person, animal, or object. The fuselage includes a canard located at a forward portion of the fuselage in front of the internal compartment. A pair of wings extend outward from the fuselage wherein each of the pair of wings contains a propulsion unit configured to provide thrust. It is desired that each propulsion unit is in fixed orientation to the fuselage and the pair of wings. A landing foot is also included and configured to rotate the fuselage into and out of a vertical orientation when on the ground. The internal compartment of the fuselage is configured to rotate to maintain an upright orientation as the fuselage is at its various orientations.

There is provided a mechanism and a device capable of increasing a degree of freedom of positioning of the center of rotation of a rotating body relative to a reference of rotation. Also, there is provided a system for using it to reduce an attitude change of a load due to an attitude change of a flying body. A rotation reference and a rotating body are connected with a rotating mechanism, provided with joints arranged so that: a link X and a link A are connected by a joint XA; a link A and a link B are connected by a joint AB; a link B and a link Y are connected by a joint BY; a link C is connected by a joint XC on the link X and a joint BC on the link B; a link D is connected by a joint AD on the link A and a joint DY on the link Y; a line connecting the joints XA and XC, and a line connecting the joints AB and BC are parallel; a line connecting the joints AB and AD, and a line connecting the joints BY and DY are parallel; a line connecting the joints XA and AB, and a line connecting the joints XC and BC are parallel; and a line connecting the joints AB and BY, and a line connecting the joints AD and DY are parallel, wherein the link X is connected to a rotation reference, or the link X is the rotation reference, and wherein the link Y is connected to a rotating body, or the link Y is the rotating body.

This disclosure describes a system and method for determining the center of gravity of a payload engaged by an automated aerial vehicle and adjusting components of the automated aerial vehicle and/or the engagement location with the payload so that the center of gravity of the payload is within a defined position with respect to the center of gravity of the automated aerial vehicle. Adjusting the center of gravity to be within a defined position improves the efficiency, maneuverability and safety of the automated aerial vehicle. In some implementations, the stability of the payload may also be determined to ensure that the center of gravity does not change or shift during transport due to movement of an item of the payload.

This disclosure describes a system and method for determining the center of gravity of a payload engaged by an automated aerial vehicle and adjusting components of the automated aerial vehicle and/or the engagement location with the payload so that the center of gravity of the payload is within a defined position with respect to the center of gravity of the automated aerial vehicle. Adjusting the center of gravity to be within a defined position improves the efficiency, maneuverability and safety of the automated aerial vehicle. In some implementations, the stability of the payload may also be determined to ensure that the center of gravity does not change or shift during transport due to movement of an item of the payload.