Abstract: A method for customizing non-destructive testing is provided and includes receiving, by a non-destructive testing (NDT) device, a stock application. The method further includes the device performing a stock NDT function in response to execution of the stock application. The stock NDT function can include a first device manipulation, a first NDT data acquisition by a device sensor, a first analysis employing data acquired by the first NDT data acquisition, or a first NDT output. The method additionally includes the device receiving a custom application after receipt of the stock application. The method also includes the device performing a custom NDT function, different from the stock NDT functions, and including at least one of a second device manipulation, a second NDT data acquisition by a sensor of the device, a second analysis employing data acquired by the second NDT data acquisition, or a second NDT output.

Abstract: A first set of data is received by a non-destructive testing device (NDT device) from a remote system. A second set of data is received by the NDT device from a sensor on the NDT device. In response to receiving the second set of data, the first set of data and the second set of data are synchronized to create a synchronized set of data by comparing the first set of data and the second set of data, identifying differences between the first set of data and the second set of data, and providing a set of data that include elements of both the first set of data and the second set of data. Synchronizing occurs automatically during an inspection. The synchronizing occurs between the NDT device and the remote system such that the synchronized set of data is present on both the NDT device and the remote system.

Abstract: A method of adaptive inspection includes receiving data characterizing one or more images of an inspection region of an industrial machine acquired by an inspection system operating based on a first set of operating parameters. The inspection region includes a site feature. The method also includes determining, by an analytical model, one or more characteristics of the inspection region from the received data characterizing the one or more images of the inspection region. The method further includes generating a control signal based on the one or more characteristics of the inspection region and/or a user input. The inspection system is configured to perform a new inspection of the inspection region based on the control signal.

Abstract: A method of adaptive inspection includes receiving data characterizing one or more images of an inspection region of an industrial machine acquired by an inspection system operating based on a first set of operating parameters. The inspection region includes a site feature. The method also includes determining, by an analytical model, one or more characteristics of the inspection region from the received data characterizing the one or more images of the inspection region. The method further includes generating a control signal based on the one or more characteristics of the inspection region and/or a user input. The inspection system is configured to perform a new inspection of the inspection region based on the control signal.

Abstract: A method of adaptive inspection includes receiving data characterizing one or more images of an inspection region of an industrial machine acquired by an inspection system operating based on a first set of operating parameters. The inspection region includes a site feature. The method also includes determining, by an analytical model, one or more characteristics of the inspection region from the received data characterizing the one or more images of the inspection region. The method further includes generating a control signal based on the one or more characteristics of the inspection region and/or a user input. The inspection system is configured to perform a new inspection of the inspection region based on the control signal.

Abstract: A method for customizing non-destructive testing is provided and includes receiving, by a non-destructive testing (NDT) device, a stock application. The method further includes the device performing a stock NDT function in response to execution of the stock application. The stock NDT function can include a first device manipulation, a first NDT data acquisition by a device sensor, a first analysis employing data acquired by the first NDT data acquisition, or a first NDT output. The method additionally includes the device receiving a custom application after receipt of the stock application. The method also includes the device performing a custom NDT function, different from the stock NDT functions, and including at least one of a second device manipulation, a second NDT data acquisition by a sensor of the device, a second analysis employing data acquired by the second NDT data acquisition, or a second NDT output.

Abstract: An embedded imaging system in one embodiment includes an encoding module, an imaging module, and a cable. The encoding module is disposed proximate to a proximal end of the system, and is configured to encode frame synchronizing information into timing information comprising a reference clock. The imaging module is disposed proximate the distal end, and includes an image capture device configured to obtain imaging information and a decoding module. The decoding control module is configured to obtain the timing information, to decode the timing information to obtain recovered frame synchronizing information, and to control the image capture device using the recovered frame synchronizing information. The cable is interposed between the proximal end and the distal end, and is configured for passage therethrough of the timing information and the imaging information.

Abstract: This invention relates to headgear for help in protecting the wearer against facial injury, especially skin damage from the elements and in particular sunburn and windburn, the headgear comprising a fabric wall which substantially surrounds the face and neck of the wearer and has in it an aperture for locating adjacent the wearer's eyes to allow vision. The wall is lightweight, flexible and porous and has stiffening means at the periphery of the aperture so as to support the aperture in open configuration in a vision-facilitating position adjacent the eyes of a wearer in use, and the wall provides protection to the wearer against ingress of particulate projectiles from around the transparent first membrane, as well as a degree of shielding from UV radiation while remaining lightweight and breathable.

Abstract: An embedded imaging system in one embodiment includes an encoding module, an imaging module, and a cable. The encoding module is disposed proximate to a proximal end of the system, and is configured to encode frame synchronizing information into timing information comprising a reference clock. The imaging module is disposed proximate the distal end, and includes an image capture device configured to obtain imaging information and a decoding module. The decoding control module is configured to obtain the timing information, to decode the timing information to obtain recovered frame synchronizing information, and to control the image capture device using the recovered frame synchronizing information. The cable is interposed between the proximal end and the distal end, and is configured for passage therethrough of the timing information and the imaging information.

Abstract: This invention relates to headgear for protecting the wearer against facial injury, especially eye injury, and in particular eye injury caused by flying particulate matter, such as may be ejected or expelled from a work-piece, the headgear comprising a first, transparent and substantially non-porous eye-protecting membrane and a fabric wall which substantially surrounds the first membrane. The wall is preferably flexible and porous and is attached to the first membrane at its periphery so as to support the first membrane in a vision-facilitating position adjacent the eyes of a wearer in use, wherein the first membrane provides eye protection against particulate projectiles while allowing the wearer to see through it, and the wall provides protection to the wearer against ingress of particulate projectiles from around the transparent first membrane.

Abstract: Systems, methods and apparatus for illuminating a mobile imaging system by use of a light source operable to emit light for status indication, pathway illumination, and/or creation of favorable lighting environment. A triggering signal originating from a photosensor arranged to receive light at the mobile imaging system, a signal indicative of movement of the mobile imaging system, or user or system command is used to adjust the lighting source. The light source can be a light emitting diode (LED), collimator lamp, halogen lamp, fluorescent lamp, organic display, or any other light-emitting technology. The light source is adjustable as to color and intensity and can indicate the mobile imaging system's condition, status, or event.

Abstract: Systems, methods and apparatus are provided through which a safety switch arrangement is assembled to prevent false activation of a subsystem in a medical system. In some embodiments, the safety switching arrangement comprises at least a first and a second type of switching element. In some embodiments, the first and the second type of switch each have an output that is processed by a processor, controller, or logic unit to produce an output signal for activating or deactivating a subsystem in the medical system.

Abstract: Systems, methods and apparatus for illuminating a mobile imaging system by use of a light source operable to emit light for status indication, pathway illumination, and/or creation of favorable lighting environment. A triggering signal originating from a photosensor arranged to receive light at the mobile imaging system, a signal indicative of movement of the mobile imaging system, or user or system command is used to adjust the lighting source. The light source can be a light emitting diode (LED), collimator lamp, halogen lamp, fluorescent lamp, organic display, or any other light-emitting technology. The light source is adjustable as to color and intensity and can indicate the mobile imaging system's condition, status, or event.

Abstract: Systems, methods and apparatus are provided through which a safety switch arrangement is assembled to prevent false activation of a subsystem in a medical system. In some embodiments, the safety switching arrangement comprises at least a first and a second type of switching element. In some embodiments, the first and the second type of switch each have an output that is processed by a processor, controller, or logic unit to produce an output signal for activating or deactivating a subsystem in the medical system.

Abstract: A system and method for remote picture editing is provided. High-resolution digital image files containing metadata are uploaded onto a hub from computers local to one or more photographers at an event. Lower-resolution copies of the digital images are made and are sent over the Internet to a web server. The web server notifies an editor that the lower-resolution images are available. The editor views the lower-resolution copies over the Internet, selects the images to be used, and using image-processing software, sets editing instructions to be applied to the image. Once the selected image is edited in accordance with the editor's instructions, the edited image is sent to a processor for final editing and application of additional metadata. The processor sends the finalized image to a reviewer for a final check before the image is sent to news and media outlets for publication.