A high speed tabletop and industrial printer is disclosed with integrated high speed RFID encoding and verification at the same time. The industrial printer simultaneously prints on and electronically encodes/verifies RFID labels, tags, and/or stickers attached to a continuous web. The industrial printer comprises a lighted sensor array for indexing the printing to the RFID tags; and a cutter powered from the industrial printer for cutting the web that the RFID tags are disposed on. The industrial printer comprises two RFID reader/writers that are individually controlled. Specifically, one of the RFID reader/writers comprises the ability to electronically encode the RFID tags while the web is moving; and the second RFID reader/writer uses an additional RFID module and antenna on the printer for verifying the data encoded to the RFID tags.

To stabilize image quality of a printed image. A thermal transfer printing apparatus according to the present invention includes a thermal head and a platen roll and forms an image on printing paper by causing the thermal head to heat an ink ribbon including a plurality of consecutive ink layers, each of which includes sequential panels of a yellow layer, a magenta layer, and a cyan layer and thereby transfer ink while transporting, between the thermal head and the platen roll, the ink ribbon and the printing paper that are superimposed on each other. The thermal transfer printing apparatus includes a sensor that detects ink content of the ink layers and a controller that controls energy applied to the thermal head during image formation on a basis of a result of the detection of the sensor.

To stabilize image quality of a printed image. A thermal transfer printing apparatus according to the present invention includes a thermal head and a platen roll and forms an image on printing paper by causing the thermal head to heat an ink ribbon including a plurality of consecutive ink layers, each of which includes sequential panels of a yellow layer, a magenta layer, and a cyan layer and thereby transfer ink while transporting, between the thermal head and the platen roll, the ink ribbon and the printing paper that are superimposed on each other. The thermal transfer printing apparatus includes a sensor that detects ink content of the ink layers and a controller that controls energy applied to the thermal head during image formation on a basis of a result of the detection of the sensor.

There are provided a thermal transfer printer and a method for producing a printed matter capable of suppressing deterioration in printing quality. A first energizing pulse is generated at the beginning of one line period. The first energizing pulse causes each heating element to perform offset heating. Second energizing pulses whose number corresponds to a tone level are generated in one line period. The second energizing pulses cause each heating element to perform heating. When the timings at which the first energizing pulse and the second energizing pulses are generated can be evenly distributed within one line period, the timings are evenly distributed within one line period. When the timings cannot be evenly distributed within one line period, the timings are distributed within one line period such that an unevenly distributed portion included in the timings is arranged in an initial period of one line period.

There are provided a thermal transfer printer and a method for producing a printed matter capable of suppressing deterioration in printing quality. A first energizing pulse is generated at the beginning of one line period. The first energizing pulse causes each heating element to perform offset heating. Second energizing pulses whose number corresponds to a tone level are generated in one line period. The second energizing pulses cause each heating element to perform heating. When the timings at which the first energizing pulse and the second energizing pulses are generated can be evenly distributed within one line period, the timings are evenly distributed within one line period. When the timings cannot be evenly distributed within one line period, the timings are distributed within one line period such that an unevenly distributed portion included in the timings is arranged in an initial period of one line period.

A method for monitoring a characteristic of a printed image of a thermal transfer printer. The method comprises providing a ribbon and a substrate at a printing location of the thermal transfer printer. The method further comprises printing an image on the substrate at the printing location by transferring ink from a region of the ribbon in a printing operation, a negative image being formed on the region of ribbon. The method further comprises transporting the region of ribbon, by a ribbon transport system, from the printing location towards an imaging location along a ribbon transport path. The method further comprises when a characteristic of the ribbon transport meets a predetermined criterion, obtaining, by an image capture system, a ribbon image of the negative image. The method further comprises processing said ribbon image to generate data indicative of the characteristic of the printed image.

A method for monitoring a characteristic of a printed image of a thermal transfer printer. The method comprises providing a ribbon and a substrate at a printing location of the thermal transfer printer. The method further comprises printing an image on the substrate at the printing location by transferring ink from a region of the ribbon in a printing operation, a negative image being formed on the region of ribbon. The method further comprises transporting the region of ribbon, by a ribbon transport system, from the printing location towards an imaging location along a ribbon transport path. The method further comprises when a characteristic of the ribbon transport meets a predetermined criterion, obtaining, by an image capture system, a ribbon image of the negative image. The method further comprises processing said ribbon image to generate data indicative of the characteristic of the printed image.

A level change point detection section detects a level change point, at which an output level switches, in a first position detection signal Ens1 generated by an encoder or a second position detection signal obtained by increasing the resolution of the Ens1. Each time a predetermined number of level change points is detected, an energization timing determination section determines the timing, at which the predetermined number of level change points have been detected, to be an energization timing for the thermal head.

A heat transfer printer performs gradation control processing for forming a first end portion and a second end portion Gbe on paper. In the gradation control processing, first heat treatment and second heat treatment are performed. Moreover, in the first heat treatment, a thermal head emits heat so that a contour of color generation by an ink sheet on a first rear end side of the first end portion is aligned parallel to a main scanning direction. In the second heat treatment, the thermal head emits the heat so that a contour of the color generation by the ink sheet on a second leading end side of the second end portion is aligned parallel to the main scanning direction.

A method and apparatus for expanding a color gamut of a direct thermal printer is described. The method includes, in a three-color direct thermal printer having at least a print head, the print head including print head elements, dynamically adjusting a duty cycle of at least one of the colors depending on the color to be printed in each pixel of an image.