Patents by Inventor Scott W. Lea
Scott W. Lea has filed for patents to protect the following inventions. This listing includes patent applications that are pending as well as patents that have already been granted by the United States Patent and Trademark Office (USPTO).
-
Patent number: 10625427Abstract: Systems and methods for automating robotic end effector alignment using real-time data from multiple distance sensors to control relative translational and rotational motion. In accordance with one embodiment, the alignment process involves computation of offset distance and rotational angles to guide a robotic end effector to a desired location relative to a target object. The relative alignment process enables the development of robotic motion path planning applications that minimize on-line and off-line motion path script creation, resulting in an easier-to-use robotic application. A relative alignment process with an independent (off-board) method for target object coordinate system registration can be used. One example implementation uses a finite-state machine configuration to control a holonomic motion robotic platform with rotational end effector used for grid-based scan acquisition for non-destructive inspection.Type: GrantFiled: June 14, 2017Date of Patent: April 21, 2020Assignee: The Boeing CompanyInventors: James J. Troy, Gary E. Georgeson, Scott W. Lea, Daniel James Wright
-
Patent number: 10585167Abstract: Systems and methods for performing relative object localization using a local positioning system. The process in accordance with one embodiment solves the problem of determining the location (i.e., the position and orientation) of an object relative to a previous location of the object, or relative to another object, without the need for known 3-D data point positions in the environment. The process in accordance with another embodiment solves the problem of determining the location of the measurement instrument relative to a previous location of the measurement instrument using visible feature points on a target object as a reference, again without the need for known 3-D data point positions. The process in accordance with a further embodiment is capable of determining the locations of multiple objects relative to each other.Type: GrantFiled: April 17, 2019Date of Patent: March 10, 2020Assignee: The Boeing CompanyInventors: James J. Troy, Scott W. Lea, Gary E. Georgeson
-
Publication number: 20200030962Abstract: Apparatus and methods for providing gravity compensation to a cable-suspended, vacuum-adhered, tool-equipped crawler vehicle traveling along and following the contour of a non-level surface during the execution of an automated maintenance operation. One technical feature shared by multiple embodiments of the gravity-compensating systems is that a cable spool is operated to wind a portion of the cable from which the vacuum-adhered crawler vehicle is suspended to generate a tensile force that counteracts a gravitational force being exerted on the crawler vehicle during movement. Rotation of the cable spool may be driven by a motor or by a tensioning spring.Type: ApplicationFiled: July 25, 2018Publication date: January 30, 2020Applicant: The Boeing CompanyInventors: Gary E. Georgeson, James J. Troy, Scott W. Lea
-
Publication number: 20200003734Abstract: A dual function non-destructive inspection apparatus comprises a frame structure, a thermographic inspection system, a displacement system, and an ultrasonic inspection system. The frame structure has a channel, a first end, and a second end. The channel extends through the frame structure from the first end to the second end. The thermographic inspection system is associated with the first end of the frame structure. The displacement system is connected to the second end of the frame structure. The ultrasonic inspection system is connected to the displacement system such that the displacement system moves the ultrasonic inspection system relative to the channel of the frame structure.Type: ApplicationFiled: June 29, 2018Publication date: January 2, 2020Inventors: James J. Troy, Daniel J. Wright, Scott W. Lea, Gary Ernest Georgeson
-
Publication number: 20190367057Abstract: An example system for inspecting railcar axles includes a flash source, an infrared camera, and a trigger sensor. The flash source is configured to apply a thermal pulse toward a surface of a railcar axle of a railcar wheelset, while the railcar wheelset is on a track. The infrared camera is configured to capture infrared data indicative of a thermal response of the surface of the railcar axle to the thermal pulse. The trigger sensor is configured to trigger the flash source to apply the thermal pulse based on a position of the railcar wheelset on the track. The example system can also include a processor configured to determine whether the captured infrared data is indicative of a crack on the surface of the railcar axle, and a vision camera configured to capture an image of the surface of the railcar axle.Type: ApplicationFiled: June 5, 2018Publication date: December 5, 2019Inventors: Gary E. Georgeson, Morteza Safai, Tyler M. Holmes, Scott W. Lea, Jyani Vaddi
-
Publication number: 20190339659Abstract: Situational-awareness controllers and methods to increase situational-awareness for an actor associated with a triggering event are described. An example method includes in response to receiving a notification of a triggering event generated by at least one sensor, a computing device accessing information that includes related to an actor associated with the triggering event. The computing device correlates the information to a compilation of historical information by (i) determining whether the actor's location is associated with one or more safety events stored as part of the compilation of historical information and (ii) determining a risk level of the actor based on whether the one or more associated safety events occurred within a predetermined range of time from the time associated with the triggering event. The computing device generates a command based on a result of the correlating and sends the command to at least one controllable device.Type: ApplicationFiled: July 18, 2019Publication date: November 7, 2019Inventors: Gary E. Georgeson, James J. Troy, Scott W. Lea, Daniel J. Wright
-
Publication number: 20190331620Abstract: Systems and methods for non-destructive inspection (NDI) of target objects having non-planar surfaces (such as aircraft components having internal stiffeners). A robotic NDI platform is equipped with an NDI sensor and a laser-based alignment system. The laser-based alignment system is operated in a manner to acquire surface profile information in an area of interest on a non-planar surface of the target object. Then the acquired surface profile data is processed by a computer to generate a motion plan for automatically guiding the robotic NDI platform and the NDI sensor to the correct locations, where images of the area of interest may be captured.Type: ApplicationFiled: April 25, 2018Publication date: October 31, 2019Applicant: The Boeing CompanyInventors: James J. Troy, Scott W. Lea, Gary E. Georgeson, Daniel James Wright
-
Publication number: 20190311555Abstract: A ground-based visual-inspection system includes a ground-based visual-inspection apparatus and a control system. The ground-based visual-inspection apparatus includes a mobile base, an actuatable arm coupled to the mobile base, and an effector coupled to the actuatable arm. The actuatable arm is locatable in a three dimensional space. The end effector includes a camera configured to capture images of a structure, such as an aircraft. The control system is configured to determine location information of the camera relative to a reference location and associate the location information with the images.Type: ApplicationFiled: April 4, 2018Publication date: October 10, 2019Inventors: James J. Troy, Scott W. Lea, Daniel J. Wright, Gary E. Georgeson
-
Publication number: 20190300135Abstract: Apparatus and methods for measuring a position of a point on a submerged surface. The apparatus includes: a platform; a liquid-tight pressure vessel fixedly coupled to the platform, wherein the liquid-tight pressure vessel is formed in part by an optically transparent enclosure; a pan-tilt mechanism coupled to the platform and disposed inside the liquid-tight pressure vessel; a camera mounted to the pan-tilt mechanism; a laser range meter affixed to the camera; and a refractive index sensor coupled to and disposed outside the liquid-tight pressure vessel. In accordance with one proposed implementation, the optically transparent enclosure is spherical, the pan-tilt mechanism has a pan axis and a tilt axis that intersect at a center of the optically transparent enclosure, and the laser range meter is located to emit a laser beam that is perpendicular to the optically transparent enclosure.Type: ApplicationFiled: March 27, 2018Publication date: October 3, 2019Applicant: The Boeing CompanyInventors: James J. Troy, Scott W. Lea, Gary E. Georgeson
-
Patent number: 10422627Abstract: Systems and methods that provide a framework for location tracking of a movable target component or device (e.g., an automated device or a hand-operated device) to accurately cover an area of interest along a specified path or in a specified region. Grid patterns are projected onto a surface of a workpiece or a part. The projected grid lines may be straight or curved. Straight grid lines can be parallel or intersecting. The grid pattern may include a path to be followed. The lines of the projected grid pattern are detected by a grid detection sensor which is mounted onboard the movable target component or device. Information from the grid detection sensor is fed to a location mapping program. The systems and methods also enable navigation for use in automated and autonomous manufacturing and maintenance operations, as well as other tracking-based applications.Type: GrantFiled: November 30, 2018Date of Patent: September 24, 2019Assignee: The Boeing CompanyInventors: Gary E. Georgeson, James J. Troy, Scott W. Lea
-
Patent number: 10409252Abstract: Situational-awareness controllers and methods to increase situational-awareness for an actor associated with a triggering event are described. An example method includes in response to receiving a notification of a triggering event generated by at least one sensor, a computing device accessing information that includes related to an actor associated with the triggering event. The computing device correlates the information to a compilation of historical information by (i) determining whether the actor's location is associated with one or more safety events stored as part of the compilation of historical information and (ii) determining a risk level of the actor based on whether the one or more associated safety events occurred within a predetermined range of time from the time associated with the triggering event. The computing device generates a command based on a result of the correlating and sends the command to at least one controllable device.Type: GrantFiled: May 12, 2017Date of Patent: September 10, 2019Assignee: The Boeing CompanyInventors: Gary E. Georgeson, James J. Troy, Scott W. Lea, Daniel J. Wright
-
Publication number: 20190265721Abstract: A method for navigating a sensor-equipped mobile platform through an through an environment to a destination, the method including: capturing a first image in a first state of illumination; capturing a second image in a second state of illumination; generating a difference image from said first image and said second image; locating an imaging target based on said difference image, said imaging target including a machine-readable code embedded therein, said machine-readable code including navigation vector data; extracting said navigation vector data from said machine-readable code; and using said extracted navigation vector data to direct the navigation of the mobile platform through the environment to a destination.Type: ApplicationFiled: February 26, 2018Publication date: August 29, 2019Applicant: The Boeing CompanyInventors: James J. Troy, Gary E. Georgeson, Scott W. Lea
-
Publication number: 20190242971Abstract: Systems and methods for performing relative object localization using a local positioning system. The process in accordance with one embodiment solves the problem of determining the location (i.e., the position and orientation) of an object relative to a previous location of the object, or relative to another object, without the need for known 3-D data point positions in the environment. The process in accordance with another embodiment solves the problem of determining the location of the measurement instrument relative to a previous location of the measurement instrument using visible feature points on a target object as a reference, again without the need for known 3-D data point positions. The process in accordance with a further embodiment is capable of determining the locations of multiple objects relative to each other.Type: ApplicationFiled: April 17, 2019Publication date: August 8, 2019Applicant: The Boeing CompanyInventors: James J. Troy, Scott W. Lea, Gary E. Georgeson
-
Patent number: 10347109Abstract: An automated human personnel fall arresting system including a holonomic base platform, a boom arm movably mounted to and depending from the base platform, at least a portion of the arm being movable in three degrees-of-freedom relative to the base platform, a tether supported by the arm, an operator harness coupled to the tether so as to be dependent from the arm, at least one sensor disposed on the arm and configured to sense movement of the portion of the arm in two degrees-of-freedom of the three degrees-of-freedom, and a controller mounted to the base platform and communicably coupled to the at least one sensor, the controller being configured to automatically control position of the base platform in two orthogonal translational directions and one rotation direction controlled independently from translation, relative to the operator harness, based on signals from the at least one sensor.Type: GrantFiled: November 8, 2016Date of Patent: July 9, 2019Assignee: The Boeing CompanyInventors: James J. Troy, Gary E. Georgeson, Scott W. Lea, Daniel J. Wright, Karl E. Nelson
-
Publication number: 20190173574Abstract: Systems and methods for high-speed non-destructive inspection of a half- or full-barrel-shaped workpiece, such as a barrel-shaped section of an aircraft fuselage. Such workpieces can be scanned externally using a mobile (e.g., translating) arch gantry system comprising a translatable arch frame disposed outside the fuselage section, a carriage that can travel along a curved track carried by the arch frame, a radially inward-extending telescopic arm having a proximal end fixedly coupled to the carriage, and an NDI sensor unit coupled to a distal end of the telescoping arm. The stiffeners of the fuselage sections can be scanned using a mobile scanner platform disposed inside the fuselage section, which platform comprises a radially outward-extending telescopic arm rotatably coupled to a mobile (e.g., holonomic or linear motion) platform and an NDI sensor unit coupled to a distal end of the telescoping arm.Type: ApplicationFiled: February 5, 2019Publication date: June 6, 2019Applicant: The Boeing CompanyInventors: Gary E. Georgeson, Barry A. Fetzer, James J. Troy, Scott W. Lea
-
Patent number: 10310054Abstract: Systems and methods for performing relative object localization using a local positioning system. The process in accordance with one embodiment solves the problem of determining the location (i.e., the position and orientation) of an object relative to a previous location of the object, or relative to another object, without the need for known 3-D data point positions in the environment. The process in accordance with another embodiment solves the problem of determining the location of the measurement instrument relative to a previous location of the measurement instrument using visible feature points on a target object as a reference, again without the need for known 3-D data point positions. The process in accordance with a further embodiment is capable of determining the locations of multiple objects relative to each other.Type: GrantFiled: March 21, 2014Date of Patent: June 4, 2019Assignee: The Boeing CompanyInventors: James J. Troy, Scott W. Lea, Gary E. Georgeson
-
Patent number: 10286556Abstract: A method and apparatus for performing an operation on a workpiece using a multi-axis compliant end-effector for attachment to a robotic device. The end-effector is positioned at a nominal location of a workpiece feature on which the operation is to be performed. The end-effector is passively aligned with the workpiece feature by contacting the end-effector with the workpiece feature. The operation is performed on the workpiece feature in response to aligning the end effector with the workpiece feature.Type: GrantFiled: October 16, 2016Date of Patent: May 14, 2019Assignee: The Boeing CompanyInventors: James J. Troy, Daniel J. Wright, Scott W. Lea
-
Publication number: 20190107382Abstract: Systems and methods that provide a framework for location tracking of a movable target component or device (e.g., an automated device or a hand-operated device) to accurately cover an area of interest along a specified path or in a specified region. Grid patterns are projected onto a surface of a workpiece or a part. The projected grid lines may be straight or curved. Straight grid lines can be parallel or intersecting. The grid pattern may include a path to be followed. The lines of the projected grid pattern are detected by a grid detection sensor which is mounted onboard the movable target component or device. Information from the grid detection sensor is fed to a location mapping program. The systems and methods also enable navigation for use in automated and autonomous manufacturing and maintenance operations, as well as other tracking-based applications.Type: ApplicationFiled: November 30, 2018Publication date: April 11, 2019Applicant: The Boeing CompanyInventors: Gary E. Georgeson, James J. Troy, Scott W. Lea
-
Publication number: 20190094149Abstract: Systems and methods for measuring the distance to a target object and acquiring scale and point-to-point distance information for that target object in an environment using a remotely operated flying platform, such as an unmanned aerial vehicle (UAV). The system uses on-board sensors and processing techniques to provide discrete or continuous measurements of the distances between points on a target object or the scale of the target object. The addition of on-board three-dimensional measurement capabilities to UAVs (or other flying platforms) allows the collection of distance data. Having this capability enables these systems to acquire distances between points on a single object, such as determining the true scale factors of items in images captured by the UAV, in the course of performing metrology-related tasks.Type: ApplicationFiled: September 25, 2017Publication date: March 28, 2019Applicant: The Boeing CompanyInventors: James J. Troy, Gary E. Georgeson, Scott W. Lea
-
Publication number: 20190098221Abstract: Systems and methods for measuring the distance to a target object and acquiring three-dimensional coordinates, scale information, and point-to-point distance information for that target object in an environment using a remotely operated cable-suspended platform. The system uses on-board sensors and processing techniques to provide discrete or continuous measurements of the distances between points on a target object or the scale of the target object. The addition of on-board three-dimensional measurement capabilities to cable-suspended platforms enables these systems to acquire three-dimensional position data defined in the coordinate system of the environment, determine distances between objects or between points on the same object. The system can also be used to determine the scale factors of items in images captured by a camera carried by the cable-suspended platform, in the course of performing metrology-related tasks.Type: ApplicationFiled: December 6, 2017Publication date: March 28, 2019Applicant: The Boeing CompanyInventors: James J. Troy, Gary E. Georgeson, Scott W. Lea