A printer may be used to print on print media, such as labels, where the print media, as fed through the print, spans substantially less than the full width of the printhead and platen. This may result in uneven print pressure across the print media during the print process. The uneven print pressure, in turn, may result in an uneven print density on the print media, which causes poor print quality. A system and method is employed with identifies the uneven print pressure, and compensates for the uneven print pressure to ensure consistent print density and good print quality. Along segments of the printhead which apply a below average pressure to the print media, the printhead is configured to apply a proportionately higher density of an appropriate contrast-inducing element, such as ink or heat. Along segments of the printhead which apply an above average pressure to the print media, the printhead is configured to apply a proportionately lower density of an appropriate contrast-inducing element, such as ink or heat.

A printer includes a thermal head having a plurality of heating elements to print on a paper that is conveyed thereto, a controller configured to control a speed of the paper that is conveyed and an amount of power supplied to the heating elements, and a processor configured to determine from image data of an image that is to be printed on the paper using the thermal head whether or not a character and a figure other than the character are to be simultaneously printed and instruct the controller based on the determination. The processor instructs the controller to set the speed of the paper to a first speed which is slower than a second speed, which is the speed for printing the character without the figure, upon determining that the character and the figure are to be simultaneously printed.

A method for printing includes analyzing print quality requirements for a printing area; adjusting settings for heater elements (e.g., energy and/or firing durations) of strobe lines based on the requirements analysis; and providing a plurality of individual strobe signals to the strobe lines. The strobe signals can be transmitted simultaneously, for example with a field-programmable gate array. Analyzing print quality requirements can include separating the printing area into one or more areas of interest, such as rows and/or columns. For each area of interest individual print quality settings (e.g., darkness, contrast, and/or media sensitivity) may be selected.

A recording apparatus includes a recording head including a plurality of heating elements, a sheet-like recording medium formed of a plurality of laminated color-developing layers for developing a plurality of colors. A first condition is satisfied when a subsequent pixel, located at the same position as a target pixel to be recorded following the target pixel, is a pixel for developing a color of a bottom color-developing layer of the recording medium. In a case where a value of the target pixel in the image data is a predetermined value and does not satisfy the first condition, the pulse control unit controls the pulse so that a thermal energy to be applied to the recording medium by the recording head in forming the target pixel is lower than if the first condition is satisfied.

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. The printer provides for successive writes to various memory blocks and optimizes the communication sequence between the interrogator and tag.

The present printing apparatus includes a printing section including a thermal head and a film transfer motor for transferring a transfer film, a memory for storing printing data of different component colors and a control section for controlling the printing section. The control section adjusts the image length at the time of forming an image of each of the component colors on the transfer film by means of the thermal head and printing data of the component color according to the gradation values of the pixels of the pixel group corresponding to a line running in the main scanning direction of the thermal head and the image forming ratio representing the ratio of the number of pixels having the component color relative to the number of the pixels of the pixel group corresponding to the line in the printing data for the component color stored in the memory.

A printing device includes a thermal head and a head controller. The head controller acquires a number of heater elements to energize based on the line print data, and determines an energization time of one or more heater elements corresponding to the line print data according to a result of comparison between the number of heater elements to energize and a first threshold, wherein in a case where a width of an ink ribbon heated by the energization is equal to or wider than a second threshold, the first threshold being set to be a value that is greater than a value that is set for the first threshold when the width of the ink ribbon heated by the energization is narrower than the second threshold.

A printing device includes a thermal head and a head controller. The head controller acquires a number of heater elements to energize based on the line print data, and determines an energization time of one or more heater elements corresponding to the line print data according to a result of comparison between the number of heater elements to energize and a first threshold, wherein in a case where a width of an ink ribbon heated by the energization is equal to or wider than a second threshold, the first threshold being set to be a value that is greater than a value that is set for the first threshold when the width of the ink ribbon heated by the energization is narrower than the second threshold.

An image processor performs: determining a dot value indicating a dot formation state, the determining including: in a case where a target pixel is not an edge pixel and a first dot forming condition is satisfied, setting the dot value to a value indicating forming a first dot; and in a case where a second dot forming condition is satisfied, setting the dot value to a value indicating forming a second dot; determining a distribution error value, the determining including: in the case where the target pixel is not the edge pixel and the first dot forming condition is satisfied, setting the distribution error value to a value corresponding to a density of the first dot; and in the case where the second dot forming condition is satisfied, setting the distribution error value to a smaller value than a value corresponding to a density of the second dot.

A printer includes a controller configured to perform a first printing process to control a thermal head to print a first image with a first density, store first print data for identifying the first image and first density data for identifying the first density into a first memory device attached to an attachment holder, when a second memory device storing second print data and second density data is attached to the attachment holder, acquire from the second memory device the second print data and the second density data stored into the second memory device by another printer, and perform a second printing process to control the thermal head to print a second image with a second density, the second image being identified based on the acquired second print data, the second density being identified based on the acquired second density data.