Abstract: A monitoring system for an aircraft which includes a laser secured to a fuselage of the aircraft and a laser beam target device secured to a wing of the aircraft, wherein the laser is positioned to emit a laser beam onto the laser beam target device for ascertaining a deflection of the wing. A method is also provided for sensing the deflection of a portion of a wing of an aircraft which includes the steps of emitting a laser beam from a laser secured to the fuselage of an aircraft and receiving the laser beam at a laser beam target device secured to a wing of the aircraft. The method further includes the step of transmitting location information of the position of the laser beam at the laser beam target device to a controller of a gimbal wherein the gimbal secures the laser to the fuselage of the aircraft.

Abstract: A system which includes a first light beam locating sensor associated with a first position to be located on a wing of an aircraft. The first light beam locating sensor senses a first light beam at an identifiable position on the first light beam locating sensor. A processor is configured to receive a first signal from the first light beam locating sensor wherein the first signal includes a first identifiable position on the first light beam locating sensor. The processor is configured to determine a location of the first position on the wing and perform a first comparison of the location of the first position on the wing to a predetermined analyzed location of the first position on the wing.

Abstract: Embodiments provide a transitional element that bridges a gap between an edge of a flight control surface and an edge of a non-movable portion of an airframe. In one embodiment, a transitional element bridges a gap between an edge of a flight control surface and an edge of a non-movable portion of an airframe. The transitional element includes a plurality of ribs that span the gap. Each of the plurality of ribs has a contour that corresponds to the flight control surface and is configured to pivot a portion of a rotated angle of the flight control surface to generate a transitional surface across the gap.

Abstract: A monitoring system for an aircraft which includes a laser secured to a fuselage of the aircraft and a laser beam target device secured to a wing of the aircraft, wherein the laser is positioned to emit a laser beam onto the laser beam target device for ascertaining a deflection of the wing. A method is also provided for sensing the deflection of a portion of a wing of an aircraft which includes the steps of emitting a laser beam from a laser secured to the fuselage of an aircraft and receiving the laser beam at a laser beam target device secured to a wing of the aircraft. The method further includes the step of transmitting location information of the position of the laser beam at the laser beam target device to a controller of a gimbal wherein the gimbal secures the laser to the fuselage of the aircraft.

Abstract: A system which includes a first light beam locating sensor associated with a first position to be located on a wing of an aircraft. The first light beam locating sensor senses a first light beam at an identifiable position on the first light beam locating sensor. A processor is configured to receive a first signal from the first light beam locating sensor wherein the first signal includes a first identifiable position on the first light beam locating sensor. The processor is configured to determine a location of the first position on the wing and perform a first comparison of the location of the first position on the wing to a predetermined analyzed location of the first position on the wing.

Abstract: Embodiments provide a transitional element that bridges a gap between an edge of a flight control surface and an edge of a non-movable portion of an airframe. In one embodiment, a transitional element bridges a gap between an edge of a flight control surface and an edge of a non-movable portion of an airframe. The transitional element includes a plurality of ribs that span the gap. Each of the plurality of ribs has a contour that corresponds to the flight control surface and is configured to pivot a portion of a rotated angle of the flight control surface to generate a transitional surface across the gap.

Abstract: Active strut apparatus for use with aircraft and related methods are disclosed. An example apparatus includes a first strut having a first end and a second end opposite the first end, the first end of the first strut is operatively coupled to a fuselage of an aircraft and the second end of the first strut is operatively coupled to a wing of the aircraft, and a first actuator is operatively coupled to the first strut to change an effective length of the first strut.

Abstract: A method for managing a flight control surface system. A leading edge device is moved on a leading edge from an undeployed position to a deployed position. The leading edge device has an outer surface, an inner surface, and a deformable fairing attached to the leading edge device such that the deformable fairing covers at least a portion of the inner surface. The deformable fairing changes from a deformed shape to an original shape when the leading edge device is moved to the deployed position. The leading edge device is then moved from the deployed position to the undeployed position, wherein the deformable fairing changes from the original shape to the deformed shape.

Abstract: Active strut apparatus for use with aircraft and related methods are disclosed. An example apparatus includes a first strut having a first end and a second end opposite the first end, the first end of the first strut is operatively coupled to a fuselage of an aircraft and the second end of the first strut is operatively coupled to a wing of the aircraft, and a first actuator is operatively coupled to the first strut to change an effective length of the first strut.

Abstract: A method for managing a flight control surface system. A leading edge device is moved on a leading edge from an undeployed position to a deployed position. The leading edge device has an outer surface, an inner surface, and a deformable fairing attached to the leading edge device such that the deformable fairing covers at least a portion of the inner surface. The deformable fairing changes from a deformed shape to an original shape when the leading edge device is moved to the deployed position. The leading edge device is then moved from the deployed position to the undeployed position, wherein the deformable fairing changes from the original shape to the deformed shape.

Abstract: A synthetic jet actuator employs a case having a cavity with an orifice. An intermediate interface is contained within the case adjacent the cavity. The intermediate interfaced is excited in a sloshing mode to expand or reduce the volume of the cavity thereby entraining air into or expelling air from the cavity.

Abstract: A method and apparatus for managing a flight control surface system. A leading edge device is moved on a leading edge from an undeployed position to a deployed position. The leading edge device has an outer surface, an inner surface, and a deformable fairing attached to the leading edge device such that the deformable fairing covers at least a portion of the inner surface. The deformable fairing changes from a deformed shape to an original shape when the leading edge device is moved to the deployed position. The leading edge device is then moved from the deployed position to the undeployed position, wherein the deformable fairing changes from the original shape to the deformed shape.

Abstract: A method and apparatus for managing a flight control surface system. A leading edge section on a wing of an aircraft is extended into a deployed position. A deformable section connects the leading edge section to a trailing section. The deformable section changes from a deformed shape to an original shape when the leading edge section is moved into the deployed position. The leading edge section on the wing is moved from the deployed position to an undeployed position. The deformable section changes to the deformed shape inside of the wing.

Abstract: A variable porosity system for an aircraft includes a first layer, a second layer and an actuator mechanism. Each of the first and second layers has at least one pore and are slidable relative to one another. The actuator mechanism is operative to move the first and second layers relative to one another such that the pores are movable into and out of at least partial alignment with one another to allow for fluid communication therebetween. At least one of the first and second layers is substantially continuous with an outer mold line surface of an aerodynamic member such as an aircraft wing. The actuator mechanism is configured to modulate the frequency of the opening and closing of the pores with respect to flight conditions of an aircraft.

Abstract: A system and method for enabling controlled twisting of a tip of a wing in response to the aerodynamic forces experienced by the wing. The structural stiffness of the wing is modulated to modulate the twist of the wing in the presence of aerodynamic forces.

Abstract: A system for monitoring the free play in aircraft control surfaces includes one or more accelerometers secured in or on the aircraft control surfaces and a computer system connected to the one or more accelerometers and to one or more control surface actuators to selectively activated to selectively activate a control surface and send a reading from the control surface to the computer system. The computer system includes means to plot the readings from the one or more accelerometers on the control surfaces to plot a curve of the free play in the selected control surface. The method of the invention utilizes the one or more accelerometers placed in or on the aircraft control surfaces and connects them to the aircraft's flight control computer or a similar computer to receive signals originated by vibrating the control surfaces and plotting curves of the free play measured in the control surfaces.

Abstract: Circuits and methods for use on a mobile platform including a flight control system, a structure, an aerodynamic surface, and an actuator operatively coupled to the surface to control the surface. The circuit includes a first and a second input, a summing element, and an output. The first input accepts commands from the flight control system while the second input accepts a vibration signal from the structure. The summing element communicates with the inputs and sums the signal and the command. In turn, the summing element controls the actuator with the summed signal and command.

Abstract: A system and method for enabling controlled twisting of a tip of a wing in response to the aerodynamic forces experienced by the wing. The structural stiffness of the wing is modulated to modulate the twist of the wing in the presence of aerodynamic forces.

Abstract: An airborne mobile platform may have a wing having a length and a chord wise dimension, and a plurality of elongated structural components extending span-wise along the length of the wing. The elongated structural components may each have a localized hinge area. A device may be used for manipulating the elongated structural component to position the localized hinge area to selectively change a hinge line of the wing in response to an airflow over the wing.

Abstract: A system and method of performing aeroelastic analysis using a neural network. Input parameters, such as mass and location, contributing to aeroelastic characterization are determined and constrained. A model of a structure to be analyzed can be constructed. The model can include a number of locations where the input parameters can be varied. The aeroelastic characteristic of the structure can be analyzed using a finite element model to determine a number of output characteristics, each of which can correspond to at least one of a plurality of input samples. A neural network can be generated for determining the aeroelastic characteristic based on input parameters. The input sample/output characteristic pairs can be used to train the neural network. The weights and bias values from the trained neural network can be used to generate a non-linear transfer function that generates the aeroelastic characteristic in response to input parameters.