Abstract: A method for forming a robotic vehicle. The method may involve forming a body and arranging a plurality of movable legs to project from the body for propelling the body over a surface. An actuator may be carried by the body to selectively engage and disengage different ones of the movable legs to cause a motion of the body, and thus the robotic vehicle, to travel over the surface.

Abstract: Presented is a system and method for distributed operation of Local Positioning Systems (LPS). A method includes establishing a network connection with a local controller and providing a user interface for sending device commands to an LPS associated with the local controller, and may include requesting a network address of a server for streaming video. The user interface can control a plurality of LPS units and the local controller can accept device commands from a plurality of user interfaces. A system includes a local system with interfaces to an LPS and a network that directs device control messages to the LPS from one or more remote systems, and a remote system that establishes network connections with one or more local systems and provides a user interface for sending device control messages to the one or more LPS units.

Abstract: A method and apparatus comprising an energy source, a position system, and a movement system. The energy source is configured to generate a beam of energy directed at an area on a target for a vehicle. The position system is configured to identify a first position of the area on the target at which the beam of energy is directed. The movement system is configured to move the vehicle in a manner that reduces a difference between the first position of the area on the target at which the beam of energy is directed and a reference position on the target.

Abstract: Holonomic-motion ground vehicles (i.e., mobile platforms) that are capable of controlled movement across non-level surfaces, while carrying one or more non-destructive inspection sensors or other tools. The mobile platform comprises a frame having four (or a multiple of four) Mecanum wheels, each wheel driven by a respective independently controlled motor, and further having a plurality (e.g., two) of independently controlled suction devices. The Mecanum wheels enable holonomic motion, while the suction devices facilitate sufficiently precise control of motion on non-level surfaces.

Abstract: A system comprising a tractor vehicle, at least one trailer vehicle and a skin between and in contact with the tractor and trailer vehicles. One of the vehicles is disposed in a non-inverted position above the skin and the other is inverted and below the skin. The trailer vehicle comprises one or more magnets, while the tractor vehicle comprises one or more magnets magnetically coupled to each opposing magnet on the trailer vehicle. The vehicles may have mutually opposing permanent magnets in one-to-one relationship. Alternatively, each permanent magnet on the trailer vehicle could be opposed by one or more electro-permanent magnets on the tractor vehicle. The system further comprises means for maintaining the magnetic attraction force within a range as the vehicles move along a portion of the skin having a varying thickness.

Abstract: A system for inspecting a test article incorporates a diagnostic imaging system for a test article. A command controller receives two dimensional (2D) images from the diagnostic imaging system. A three dimensional (3D) computer aided design (CAD) model visualization system and an alignment system for determining local 3D coordinates are connected to the command controller. Computer software modules incorporated in the command controller are employed, in aligning, the 2D images and 3D CAD model responsive to the local 3D coordinates. The 2D images and 3D CAD model are displayed with reciprocal registration. The alignment system is then directed to selected coordinates in the 2D images or 3D CAD model.

Abstract: An apparatus comprises an inspection vehicle, a sensor system, a positioning system, a controller, and a support system. The inspection vehicle is configured to move on a surface of an object. The sensor system is associated with the inspection vehicle and is configured to generate information about the object when the inspection vehicle is on the surface of the object. The positioning system is configured to determine a location of the inspection vehicle on the object. The controller is configured to control movement of the inspection vehicle using the positioning system and control operation of the sensor system. The support system is connected to the inspection vehicle and is configured to support the inspection vehicle in response to an undesired release of the inspection vehicle from the surface of the object.

Abstract: A local positioning system including a sighting device for indicating an aim point on a target object, the target object having a local coordinate system, an articulation mechanism connected to the sighting device to effect movement of the sighting device about at least two independent axes, and a controller in communication with the articulation mechanism, the controller being configured to control a velocity of the sighting device about each of the independent axes to obtain desired movement of the aim point on the target object in the local coordinate system.

Abstract: Position determining systems and methods are provided. A particular portable device includes a calibration component to communicate with a local positioning system to determine an initial position and orientation of the portable device within a local coordinate system associated with a target structure. The portable device also includes at least one movement sensor to detect movement of the portable device. The portable device further includes a processor to determine a measured position and orientation of the portable device based on the initial position and orientation of the portable device within the local coordinate system and based on the detected movement of the portable device.

Abstract: Presented is a system and method for distributed operation of Local Positioning Systems (LPS). A method includes establishing a network connection with a local controller and providing a user interface for sending device commands to an LPS associated with the local controller, and may include requesting a network address of a server for streaming video. The user interface can control a plurality of LPS units and the local controller can accept device commands from a plurality of user interfaces. A system includes a local system with interfaces to an LPS and a network that directs device control messages to the LPS from one or more remote systems, and a remote system that establishes network connections with one or more local systems and provides a user interface for sending device control messages to the one or more LPS units.

Abstract: A method is disclosed for controlling at least one remotely operated unmanned object. The method may involve defining a plurality of body movements of an operator that correspond to a plurality of operating commands for the unmanned object. Body movements of the operator may be sensed to generate the operating commands. Wireless signals may be transmitted to the unmanned object that correspond to the operating commands that control operation of the unmanned object.

Abstract: Methods are described for controlling orientation of an aim point axis of a video camera having an instrument coordinate system to track a point of interest on a movable target object and calculating positions of the point of interest in a local coordinate system in which the target object is moving. The methods include measuring pan and tilt angles of the aim point axis and distance substantially along the aim point axis and calculating a calibration matrix which transforms a position defined in the instrument coordinate system to a position defined in the local coordinate system. A system is described including an instrument and at least one computer, wherein the instrument includes a video camera and a range finder, and wherein the video camera includes an aim point axis having an adjustable orientation. In one example, the target object is adapted to move on and inspect an airplane surface.

Abstract: A first method locates a component positioned underneath a surface of a target object using a pointing instrument, wherein a position of the component in the target object coordinate system is known. The first method includes calculating an orientation of the aim point axis of the instrument in the instrument coordinate system for the aim point axis of the instrument to be aligned with the component using at least an inverse calibration matrix, the position of the component in the target object coordinate system, and inverse kinematics of the instrument. The first method also includes rotating the aim point axis of the instrument to the calculated orientation. Second and third methods also are described for locating an access panel for accessing the component and/or maintenance zones in which the component resides.

Abstract: A system and method for determining the position and orientation of a handheld device relative to a known object is presented. The system comprises a handheld device having an inertial measurement unit and a sighting device, such as a laser pointer, that are used to determine the position of the handheld device relative to a target object, such as a structure, aircraft, or vehicle. The method comprises calibrating a handheld device to find the current location of the handheld device relative to a target object, tracking the movement of the handheld device using an inertial measurement unit, and presenting an updated position of the handheld device relative to a target object.

Abstract: Methods and systems are provided for positioning a remote sensor within a target object. An articulated robotic system is coupled to the remote sensor. A positioning system determines a position of the target object to be inspected and determines a first position of the remote sensor. A control system calibrates a virtual representation of the target object with respect to the position of the target object, and tracks movement of the remote sensor relative to the target object.

Abstract: A lifting and lowering apparatus may include: at least one cable, at least one pulley connected to the at least one cable, at least one drive member connected to the at least one cable for driving the at least one cable in at least one direction, a moveable payload attachment member for attaching to a payload to be at least one of lifted and lowered, an attachment member guide attached to the moveable payload attachment member, and an alignment guide for positioning at a position. The moveable payload attachment member may be at least one of lifted and lowered by the at least one cable. Both the attachment member guide and the alignment guide may be shaped to force the attachment member guide into a pre-determined mating position and orientation against the alignment guide at the position.

Abstract: A method for forming a robotic vehicle. The method may involve forming a body and arranging a plurality of movable legs to project from the body for propelling the body over a surface. An actuator may be carried by the body to selectively engage and disengage different ones of the movable legs to cause a motion of the body, and thus the robotic vehicle, to travel over the surface.

Abstract: Position determining systems and methods are provided. A particular portable device includes a calibration component to communicate with a local positioning system to determine an initial position and orientation of the portable device within a local coordinate system associated with a target structure. The portable device also includes at least one movement sensor to detect movement of the portable device. The portable device further includes a processor to determine a measured position and orientation of the portable device based on the initial position and orientation of the portable device within the local coordinate system and based on the detected movement of the portable device.

Abstract: A method for forming a robotic vehicle. The method may involve forming a body and arranging a plurality of movable legs to project from the body for propelling the body over a surface. An actuator may be carried by the body to selectively engage and disengage different ones of the movable legs to cause a motion of the body, and thus the robotic vehicle, to travel over the surface.

Abstract: Systems and methods are disclosed for haptics-enabled teleoperation of vehicles and other devices, including remotely-controlled air, water, and land-based vehicles, manufacturing robots, and other suitable teleoperable devices. In one embodiment, a system for teleoperation of a vehicle comprises a control component configured to provide position and orientation control with haptic force feedback of the vehicle based on a position measurement of the vehicle and configured to function in a closed-loop feedback manner. In a particular embodiment, the position measurement may include six degree-of-freedom position data provided by a motion capture system to the control and/or haptic I/O components of the application. The system may also use differences in position and/or velocity between the vehicle and a haptic I/O device for feedback control.