Abstract: Methods, systems, and computer-readable media for articulating visual inspection devices are provided. For example, a method can include receiving an inspection template by a control system associated with the visual inspection device. The inspection template can include data associated with at least one point of interest in a scene viewable to the visual inspection device. The method can further include generating, by the control system, an articulation path based on the data. The method can also include actuating an electro-mechanical system of the visual inspection device according to the articulation path.

Abstract: A method of operating an inspection device includes collecting a plurality of successive image frames using an image sensor of the inspection device and displaying the plurality of successive image frames on a display of the inspection device. The method includes processing, via a processor of the inspection device, each image frame of the plurality of successive image frames by determining a motion parameter of each respective image frame and adding each respective image frame to a frame buffer when the respective image frame is motion free. The method includes receiving a control signal from a user interface of the inspection device requesting an image frame output. The method further includes determining, via the processor of the inspection device, a noise-reduced image frame from the frame buffer in response to the control signal and outputting the noise-reduced image frame in response to the control signal.

Abstract: Methods, systems, and computer-readable media for articulating visual inspection devices are provided. For example, a method can include receiving an inspection template by a control system associated with the visual inspection device. The inspection template can include data associated with at least one point of interest in a scene viewable to the visual inspection device. The method can further include generating, by the control system, an articulation path based on the data. The method can also include actuating an electro-mechanical system of the visual inspection device according to the articulation path.

Abstract: Systems and methods provided herein. In one embodiment, a borescope system includes a probe to capture images and a display a settings menu, measurements, the images captured by the probe, or any combination thereof. In addition, the borescope system a processor programmed to display a user interface to enable a user to control movement of the probe, adjust settings, navigate menus, make selections, or any combination thereof. The processor is communicatively coupled to the probe, and the display, and is programmed to instruct the borescope to enter a live menu view when an articulation mode is selected from the settings menu. In the live menu view, the processor is programmed to instruct the display to display the images captured by the probe, and to enable a user to control the movement of the probe and adjust articulation sensitivity of the probe while viewing the images on the display.

Abstract: A method of operating an inspection device includes collecting a plurality of successive image frames using an image sensor of the inspection device and displaying the plurality of successive image frames on a display of the inspection device. The method includes processing, via a processor of the inspection device, each image frame of the plurality of successive image frames by determining a motion parameter of each respective image frame and adding each respective image frame to a frame buffer when the respective image frame is motion free. The method includes receiving a control signal from a user interface of the inspection device requesting an image frame output. The method further includes determining, via the processor of the inspection device, a noise-reduced image frame from the frame buffer in response to the control signal and outputting the noise-reduced image frame in response to the control signal.

Abstract: Methods, systems, and computer-readable media for articulating visual inspection devices are provided. For example, a method can include receiving an inspection template by a control system associated with the visual inspection device. The inspection template can include data associated with at least one point of interest in a scene viewable to the visual inspection device. The method can further include generating, by the control system, an articulation path based on the data. The method can also include actuating an electro-mechanical system of the visual inspection device according to the articulation path.

Abstract: A system includes a portable non-destructive testing (NDT) device. The NDT device includes a processor configured to receive imaging data captured via a sensor of the NDT device, cause a display of the NDT device to display an image to be analyzed based on the imaging data, and cause the display to display a graphical user interface (GUI). The GUI includes a first plurality of user-selectable objects. Each of the first plurality of user-selectable objects is configured to activate one or more monitoring functions of the NDT device. The processor is also configured to cause the display to display at least a first set of the first plurality of user-selectable objects. The first set of the first plurality of user-selectable objects is configured to substantially overlay the image. The first set of the first plurality of user-selectable objects is displayed based at least in part on an inspection state of the NDT device.

Abstract: A system includes a portable non-destructive testing (NDT) device. The NDT device includes a processor configured to receive imaging data captured via a sensor of the NDT device, cause a display of the NDT device to display an image to be analyzed based on the imaging data, and cause the display to display a graphical user interface (GUI). The GUI includes a first plurality of user-selectable objects. Each of the first plurality of user-selectable objects is configured to activate one or more monitoring functions of the NDT device. The processor is also configured to cause the display to display at least a first set of the first plurality of user-selectable objects. The first set of the first plurality of user-selectable objects is configured to substantially overlay the image. The first set of the first plurality of user-selectable objects is displayed based at least in part on an inspection state of the NDT device.

Abstract: Systems and methods provided herein. In one embodiment, a borescope system includes a probe to capture images and a display a settings menu, measurements, the images captured by the probe, or any combination thereof. In addition, the borescope system a processor programmed to display a user interface to enable a user to control movement of the probe, adjust settings, navigate menus, make selections, or any combination thereof. The processor is communicatively coupled to the probe, and the display, and is programmed to instruct the borescope to enter a live menu view when an articulation mode is selected from the settings menu. In the live menu view, the processor is programmed to instruct the display to display the images captured by the probe, and to enable a user to control the movement of the probe and adjust articulation sensitivity of the probe while viewing the images on the display.

Abstract: A system includes an image capture device configured to capture an image of at least a portion of an industrial device or machinery. The system also includes a display configured to display the image. The system further includes a processor communicatively coupled to the image capture device and the display and configured to cause the display to display a graphical user interface (GUI) on the display, wherein the GUI comprises a first indicator located in user selectable first portion of the display and a window configured to display a portion of the image corresponding to a location of the first indicator, wherein the processor is configured to cause the first indicator to move to a second portion of the display in response to receiving an indication of a user interaction with the window.

Abstract: Methods, systems, and computer-readable media for articulating visual inspection devices are provided. For example, a method can include receiving an inspection template by a control system associated with the visual inspection device. The inspection template can include data associated with at least one point of interest in a scene viewable to the visual inspection device. The method can further include generating, by the control system, an articulation path based on the data. The method can also include actuating an electro-mechanical system of the visual inspection device according to the articulation path.

Abstract: A non-transitory, computer-readable medium includes computer-executable code having instructions. The instructions are configured to receive data relating to an environment, construct an image of the environment based on the received data, and display the image on a touch-screen device. The instructions are also configured to receive a control gesture via the touch-screen device and interpret the control gesture. Further, the instructions are configured to control an articulating system coupled to the device to control an orientation of a sensor configured to collect the data, control a mode of operation of the sensor, or any combination thereof based on the interpretation of the control gesture.

Abstract: A method of operating an inspection device includes collecting a plurality of successive image frames using an image sensor of the inspection device and displaying the plurality of successive image frames on a display of the inspection device. The method includes processing, via a processor of the inspection device, each image frame of the plurality of successive image frames by determining a motion parameter of each respective image frame and adding each respective image frame to a frame buffer when the respective image frame is motion free. The method includes receiving a control signal from a user interface of the inspection device requesting an image frame output. The method further includes determining, via the processor of the inspection device, a noise-reduced image frame from the frame buffer in response to the control signal and outputting the noise-reduced image frame in response to the control signal.

Abstract: The present disclosure describes an embodiment that provides a tangible, non-transitory, computer-readable medium storing instructions executable by a processor of an endoscope. The instructions include instructions to capture, using an imager in the endoscope, a first plurality of images at a first brightness level while a live video based at least in part on the first plurality of images is displayed, generate, using the processor, a baseline image by averaging or summing the first plurality of images, capture, using the imager, a second plurality of images at a plurality of brightness levels, in which the plurality of brightness levels are different from the first brightness level, and generate, using the processor, a high dynamic range image based at least in part on the baseline image and the second plurality of images, in which the high dynamic range image comprises more unsaturated pixels than the baseline image.

Abstract: A method and device for automatically identifying a point of interest (e.g., the deepest or highest point) on the surface of an anomaly on a viewed object using a video inspection device is disclosed. The video inspection device obtains and displays an image of the surface of the viewed object. A reference surface is determined along with a region of interest that includes a plurality of points on the surface of the anomaly. The video inspection device determines a depth or height for each of the plurality of points on the surface of the anomaly in the region of interest. The point on the surface of the anomaly (e.g., having the greatest depth or height) is identified as the point of interest. A profile of the object surface at the point of interest is then determined.

Abstract: A non-transitory, computer-readable medium includes computer-executable code having instructions. The instructions are configured to receive data relating to an environment, construct an image of the environment based on the received data, and display the image on a touch-screen device. The instructions are also configured to receive a control gesture via the touch-screen device and interpret the control gesture. Further, the instructions are configured to control an articulating system coupled to the device to control an orientation of a sensor configured to collect the data, control a mode of operation of the sensor, or any combination thereof based on the interpretation of the control gesture.

Abstract: Systems and methods provided herein. In one embodiment, a borescope system includes a probe to capture images and a display a settings menu, measurements, the images captured by the probe, or any combination thereof. In addition, the borescope system a processor programmed to display a user interface to enable a user to control movement of the probe, adjust settings, navigate menus, make selections, or any combination thereof. The processor is communicatively coupled to the probe, and the display, and is programmed to instruct the borescope to enter a live menu view when an articulation mode is selected from the settings menu. In the live menu view, the processor is programmed to instruct the display to display the images captured by the probe, and to enable a user to control the movement of the probe and adjust articulation sensitivity of the probe while viewing the images on the display.

Abstract: A system includes a portable non-destructive testing (NDT) device. The NDT device includes a processor configured to receive imaging data captured via a sensor of the NDT device, cause a display of the NDT device to display an image to be analyzed based on the imaging data, and cause the display to display a graphical user interface (GUI). The GUI includes a first plurality of user-selectable objects. Each of the first plurality of user-selectable objects is configured to activate one or more monitoring functions of the NDT device. The processor is also configured to cause the display to display at least a first set of the first plurality of user-selectable objects. The first set of the first plurality of user-selectable objects is configured to substantially overlay the image. The first set of the first plurality of user-selectable objects is displayed based at least in part on an inspection state of the NDT device.

Abstract: A system includes an image capture device configured to capture an image of at least a portion of an industrial device or machinery. The system also includes a display configured to display the image. The system further includes a processor communicatively coupled to the image capture device and the display and configured to cause the display to display a graphical user interface (GUI) on the display, wherein the GUI comprises a first indicator located in user selectable first portion of the display and a window configured to display a portion of the image corresponding to a location of the first indicator, wherein the processor is configured to cause the first indicator to move to a second portion of the display in response to receiving an indication of a user interaction with the window.

Abstract: The present disclosure describes an embodiment that provides a tangible, non-transitory, computer-readable medium storing instructions executable by a processor of an endoscope. The instructions include instructions to capture, using an imager in the endoscope, a first plurality of images at a first brightness level while a live video based at least in part on the first plurality of images is displayed, generate, using the processor, a baseline image by averaging or summing the first plurality of images, capture, using the imager, a second plurality of images at a plurality of brightness levels, in which the plurality of brightness levels are different from the first brightness level, and generate, using the processor, a high dynamic range image based at least in part on the baseline image and the second plurality of images, in which the high dynamic range image comprises more unsaturated pixels than the baseline image.