The present application relates to track barcode automatic mounting system and method of an automatic material handling system (AMHS), which system comprises: a running track, at whose position corresponding to an unloading port is provided a barcode mounting region; an overhead hoist transport, installed on the running track, and being moveable along the running track; a locating device, for determining whether the overhead hoist transport has moved to a designated barcode mounting region; a barcode automatic printing and mounting device, disposed on the overhead hoist transport; and a manually operated controller, for sending a movement instruction to the overhead hoist transport to control the overhead hoist transport to move to the designated barcode mounting region, and sending a print confirmation instruction to the barcode automatic printing and mounting device after the overhead hoist transport has moved to the designated barcode mounting region.

A printing system, including an atomizer operatively arranged to deliver a first ink and a printhead arranged adjacent to the atomizer, the printhead operatively arranged to deliver a second ink, the second ink being different from the first ink, wherein a print media including a dark color is operatively arranged to pass under, in order, the atomizer and the printhead.

A printing system, including an atomizer operatively arranged to deliver a first ink and a printhead arranged adjacent to the atomizer, the printhead operatively arranged to deliver a second ink, the second ink being different from the first ink, wherein a print media including a dark color is operatively arranged to pass under, in order, the atomizer and the printhead.

A printing device includes a thermal printhead with a plurality of print elements. A controller is configured to identify an out of specification status of at least one print element, wherein the controller is further configured to determine whether printing of a specific print field requires use of the print element having the out of specification status and, if so, to determine whether a print location of the specific print field can be shifted such that the print element having out of specification status will be one of (i) aligned with a gap in the specific print field or (ii) offset to one side of the specific print field. A weighing scale incorporating the printing device is also provided.

A printing device includes a thermal printhead with a plurality of print elements. A controller is configured to identify an out of specification status of at least one print element, wherein the controller is further configured to determine whether printing of a specific print field requires use of the print element having the out of specification status and, if so, to determine whether a print location of the specific print field can be shifted such that the print element having out of specification status will be one of (i) aligned with a gap in the specific print field or (ii) offset to one side of the specific print field. A weighing scale incorporating the printing device is also provided.

Methods for converting an image to source script are provided. Generally applied to thermal printers, the methods may assist users in reproducing or amending a label without actual source script. In one embodiment, a mobile device comprising a software application may be able to scan an image, for example a barcode label. The software application may use an image processing library to recognize smart object fields in the captured image, including text, barcodes, image and shapes and then may translate the smart object information to a printing language script automatically. The application may provide the capability to a user to adjust the parameters specific to each of the identified smart objects. Once the user makes the necessary changes, a script file may be generated based on the updated smart object information. Then, the label may be sent to a printer from the application itself.

Methods for converting an image to source script are provided. Generally applied to thermal printers, the methods may assist users in reproducing or amending a label without actual source script. In one embodiment, a mobile device comprising a software application may be able to scan an image, for example a barcode label. The software application may use an image processing library to recognize smart object fields in the captured image, including text, barcodes, image and shapes and then may translate the smart object information to a printing language script automatically. The application may provide the capability to a user to adjust the parameters specific to each of the identified smart objects. Once the user makes the necessary changes, a script file may be generated based on the updated smart object information. Then, the label may be sent to a printer from the application itself.

A security-enhanced document including a substrate, variable indica applied to an area of a first side of the substrate, a scratch-off-coating applied over the variable indicia to maintain the variable indicia unreadable until the scratch-off-coating is removed by being scratched off, and digital imaging applied to an area of a reverse side of the substrate from the variable indicia, wherein the digital imaging applied to the area of the reverse side of the substrate includes the same materials as the variable indicia, is uniformly spread over the area of the reverse side of the substrate, and such that the digital imaging overlaps at least 50% of the variable indica applied to the area of the first side of the substrate, such that the variable indicia exhibits an insufficient signal-to-noise ratio relative to the signal-to-noise ratio of the digital imaging on the reverse side of the substrate so that the variable indicia cannot be discerned so long as the scratch-off-coating remains intact.

A security-enhanced document including a substrate, variable indica applied to an area of a first side of the substrate, a scratch-off-coating applied over the variable indicia to maintain the variable indicia unreadable until the scratch-off-coating is removed by being scratched off, and digital imaging applied to an area of a reverse side of the substrate from the variable indicia, wherein the digital imaging applied to the area of the reverse side of the substrate includes the same materials as the variable indicia, is uniformly spread over the area of the reverse side of the substrate, and such that the digital imaging overlaps at least 50% of the variable indica applied to the area of the first side of the substrate, such that the variable indicia exhibits an insufficient signal-to-noise ratio relative to the signal-to-noise ratio of the digital imaging on the reverse side of the substrate so that the variable indicia cannot be discerned so long as the scratch-off-coating remains intact.

A method and system for writing a label (defined within a predetermined region of the sample 110), the label displaying a visible layout of light-modified regions in a predetermined spatial arrangement. The method comprises: modifying regions of a material within the label using light, wherein the modifying comprises using light of a first polarisation state to provide photo-induced optically active regions of a first type having a first optical activity state which is characteristic of having been formed by light of the first polarisation state, in order to encode covert information in the label using the locations of the first type of light-modified regions within the spatial arrangement of the label.