Abstract: A method for printing defect detection includes processing and analyzing a difference image obtained by comparing an image scanned with a verifier to a reference image. The detected defects are grouped, and the grouping is refined. Confidence level values are then assigned to the refined groups, and analysis is performed to determine if one or more servicing actions should be taken.

Abstract: Various example embodiments described herein relate to a method for synchronizing liquid crystal display (LCD) screens. In some examples, the method includes establishing, by a first device comprising a processor, a master/slave relationship with one or more other devices; determining, by the first device, a frequency associated with turning on a first LCD screen on the first device; and sending, by the first device, a signal to each of the one or more other devices, wherein the signal comprises an instruction to turn on an LCD screen on each receiving device at a same time as the first LCD screen.

Abstract: A method for printing defect detection includes processing and analyzing a difference image obtained by comparing an image scanned with a verifier to a reference image. The detected defects are grouped, and the grouping is refined. Confidence level values are then assigned to the refined groups, and analysis is performed to determine if one or more servicing actions should be taken.

Abstract: Various example embodiments described herein relate to a method for synchronizing liquid crystal display (LCD) screens. In some examples, the method includes establishing, by a first device comprising a processor, a master/slave relationship with one or more other devices; determining, by the first device, a frequency associated with turning on a first LCD screen on the first device; and sending, by the first device, a signal to each of the one or more other devices, wherein the signal comprises an instruction to turn on an LCD screen on each receiving device at a same time as the first LCD screen.

Abstract: Embodiments of the disclosure provide for improved object pathing. The improved object pathing is provided based at least in part on continuous, real-time sensor data transmitted over a high-throughput communications network that enables updating of object in real-time as changes to an environment are detected from high-fidelity, continuous, real-time sensor data.

Abstract: A method for printing defect detection includes processing and analyzing a difference image obtained by comparing an image scanned with a verifier to a reference image. The detected defects are grouped, and the grouping is refined. Confidence level values are then assigned to the refined groups, and analysis is performed to determine if one or more servicing actions should be taken.

Abstract: Various example embodiments described herein relate to a method for synchronizing liquid crystal display (LCD) screens. In some examples, the method includes establishing, by a first device comprising a processor, a master/slave relationship with one or more other devices; determining, by the first device, a frequency associated with turning on a first LCD screen on the first device; and sending, by the first device, a signal to each of the one or more other devices, wherein the signal comprises an instruction to turn on an LCD screen on each receiving device at a same time as the first LCD screen.

Abstract: A method for printing defect detection includes processing and analyzing a difference image obtained by comparing an image scanned with a verifier to a reference image. The detected defects are grouped, and the grouping is refined. Confidence level values are then assigned to the refined groups, and analysis is performed to determine if one or more servicing actions should be taken.

Abstract: A method for printing defect detection includes processing and analyzing a difference image obtained by comparing an image scanned with a verifier to a reference image. The detected defects are grouped, and the grouping is refined. Confidence level values are then assigned to the refined groups, and analysis is performed to determine if one or more servicing actions should be taken.

Abstract: A method for printing defect detection includes processing and analyzing a difference image obtained by comparing an image scanned with a verifier to a reference image. The detected defects are grouped, and the grouping is refined. Confidence level values are then assigned to the refined groups, and analysis is performed to determine if one or more servicing actions should be taken.

Abstract: Various embodiments illustrated herein disclose a latching mechanism that enables engagement of modules on a mobile scanning device. The latching mechanism includes a release switch that translates between a first position and a second position. The release switch is coupled to a latch body that includes a first tongue section and a second tongue section. The first tongue section engages with the mobile scanning device, while the second tongue section engages with an attachment member. When the release switch is moved to a first position, the mobile scanning device is disengaged. When the release switch is moved to the second position, the attachment member is disengaged.

Abstract: A method for printing defect detection includes processing and analyzing a difference image obtained by comparing an image scanned with a verifier to a reference image. The detected defects are grouped, and the grouping is refined. Confidence level values are then assigned to the refined groups, and analysis is performed to determine if one or more servicing actions should be taken.

Abstract: Various embodiments illustrated herein disclose a latching mechanism that enables engagement of modules on a mobile scanning device. The latching mechanism includes a release switch that translates between a first position and a second position. The release switch is coupled to a latch body that includes a first tongue section and a second tongue section. The first tongue section engages with the mobile scanning device, while the second tongue section engages with an attachment member. When the release switch is moved to a first position, the mobile scanning device is disengaged. When the release switch is moved to the second position, the attachment member is disengaged.

Abstract: A method for printing defect detection includes processing and analyzing a difference image obtained by comparing an image scanned with a verifier to a reference image. The detected defects are grouped, and the grouping is refined. Confidence level values are then assigned to the refined groups, and analysis is performed to determine if one or more servicing actions should be taken.

Abstract: A label marks a composite material. In one embodiment, the label may be printed with magnetically doped ink and may be embedded between layers of the composite during manufacture. In one embodiment, the label may be embedded on the surface of the composite material using a heat curable resin. In one embodiment, the label carries indicia that may be read with magnetic ink character recognition (MICR) or other magnetic scanning technology. In one embodiment, there is no need for visual contrast between the composite, label and/or indicia.

Abstract: An integral label for composite materials. The label, printed with magnetically doped ink, ink with UV components, ink with IR components may be embedded on the surface of the composite material using a heat curable resin. The indicia on the label can be read with magnetic ink character recognition (MICR) or other magnetic scanning technology or scanners that recognize UV and/or IR components. The label may be made of retro reflective material and reverse printed with opaque ink. The data carrier may be a mesh, paper, porous material, solid resin sheet or the data may be printed directly on the composite. There is no need for visual contrast between the composite, label and/or indicia.

Abstract: An integral label for composite materials. The label, printed with magnetically doped ink, may be embedded between layers of a composite during manufacture. The label may be embedded on the surface of the composite material using a heat curable resin. The indicia on the label can be read with magnetic ink character recognition (MICR) or other magnetic scanning technology. There is no need for visual contrast between the composite, label and/or indicia.