A printing system includes a printing device, a platen roller, a controller, and an interface. The printing device includes a thermal head, a ribbon drive source, and a head drive source. When receiving a print command, the controller executes head movement control for moving the thermal head and ribbon acceleration control for accelerating a transport speed of an ink ribbon to a target speed. After completion of the head movement control and the ribbon acceleration control, the controller is configured to control the thermal head to perform printing on the print medium. At least before receiving the print command, the controller is configured to determine a printable distance over which the print medium is transported from the reception of the print command till the completion of the head movement control and the ribbon acceleration control and outputs the determined printable distance through the interface.

A print apparatus includes a conveyor configured to convey a sheet along a conveyance path in a first direction. The print apparatus also includes a print head on the conveyance path, a main scan direction of the print head crossing the first direction. The print apparatus further includes a print controller configured to control the print head that in a first print mode prints images on the sheet using a first print reference position on a first end of the print head in the main scan direction and a first image direction parallel to the first direction, and in a second print mode prints images on the sheet using a second print reference position on a second end of the print head in the main scan direction and a second image direction parallel and opposite to the first image direction.

A print apparatus includes a conveyor configured to convey a sheet along a conveyance path in a first direction. The print apparatus also includes a print head on the conveyance path, a main scan direction of the print head crossing the first direction. The print apparatus further includes a print controller configured to control the print head that in a first print mode prints images on the sheet using a first print reference position on a first end of the print head in the main scan direction and a first image direction parallel to the first direction, and in a second print mode prints images on the sheet using a second print reference position on a second end of the print head in the main scan direction and a second image direction parallel and opposite to the first image direction.

According to one embodiment, an RFID tag or label printer apparatus includes a print head to print a pattern on the RFID tag, which includes an RFID chip at a predetermined mounting position. A processor is configured to receive the predetermined mounting position and label information including a print position for the pattern information to be printed on the RFID tag. The processor is configured to compare the predetermined mounting position to the print position and then control the print head to print the pattern information if the print position does not overlap a region through which the RFID chip passes when RFID tag is conveyed along a conveying direction past the print head for printing.

According to one embodiment, an RFID tag or label printer apparatus includes a print head to print a pattern on the RFID tag, which includes an RFID chip at a predetermined mounting position. A processor is configured to receive the predetermined mounting position and label information including a print position for the pattern information to be printed on the RFID tag. The processor is configured to compare the predetermined mounting position to the print position and then control the print head to print the pattern information if the print position does not overlap a region through which the RFID chip passes when RFID tag is conveyed along a conveying direction past the print head for printing.

An image forming apparatus includes a printhead configured to add energy to an image material; and a control unit configured to output, based on image data, a signal pattern for controlling energy to be added by the printhead to the image material including a plurality of color development layers that have different color development characteristic and develop colors in accordance with the added energy. When causing at least two of the plurality of color development layers to develop colors, the control unit generates, based on at least two signal patterns generated to cause the at least two color development layers to develop colors, a signal pattern of an OR of the at least two signal patterns and outputs the signal pattern.

Various embodiments disclose a method for operating a printer apparatus. The method comprising monitoring a utilization rate of each heating element in a first set of heating elements defined by a print head arrangement. Further, the method comprises generating a utilization dataset based upon monitoring of the utilization rate of each heating element in the first set of heating elements print head arrangement. Furthermore, the method includes analyzing the utilization dataset to identify one or more overutilized heating elements of the first set of heating elements. Additionally, the method includes identifying a second set of heating elements defined by the print head arrangement. The second set of heating elements comprises a portion of the first set of heating elements exclusive of the one or more overutilized heating elements. The method further includes processing a print job. The processed print job utilized the second set of heating elements during printing.

A thermal printer includes a thermal head in which a plurality of heating elements are arranged in a line, and a processor that executes a printing process of energizing the thermal head successively a predetermined number of times so at to print a printing data by causing a predetermined voltage to be applied to the thermal head the predetermined number of times in accordance with and in synchronization with strobe pulses in a strobe signal, a strobe width of each strobe pulse in the strobe signal defining a duration during which the thermal head is being applied with the predetermined voltage, wherein among the strobe pulses for the predetermined number of times of energizing the thermal head, a strobe width of at least one predetermined strobe pulse is set to be always shorter than a strobe width of another predetermined one of the strobe pulses.

There is provided an image recording apparatus including: a head; a driving element; a controller configured to output, to the driving element, a driving signal having a first voltage level or a second voltage level greater than the first voltage level; and a moving mechanism causing one of the recording medium and the head to move relative to the other of the recording medium and the head. The controller sets the voltage level of the driving signal to be the first voltage level in a case that the controller causes the head to move relative to the recording medium at the first velocity; and the controller sets the voltage level of the driving signal to be the second voltage level in a case that the controller causes the head to move relative to the recording medium at the second velocity.

A printer comprising a printhead configured to selectively cause a mark to be created on a substrate provided adjacent to the printer, the printhead having a first configuration in which the printhead is spaced apart from the printing surface and a second configuration in which the printhead is configured to press the substrate against a printing surface during a printing operation. The printer further comprises a printhead drive assembly configured to cause movement of the printhead towards and away from the printing surface between the first and second configurations, the printhead drive assembly comprising a permanent magnet and an electromagnet. When the electromagnet is in a first condition, an attractive magnetic force is generated between the permanent magnet and the electromagnet, and when the electromagnet is in a second condition, a repulsive magnetic force is generated between the permanent magnet and the electromagnet, each of said attractive and repulsive magnetic forces being configured to one of urge the printhead away from and towards the printing surface. The printhead drive assembly is configured such that, when the printhead is in each of the first and second configurations, it is retained in that configuration by the printhead drive assembly when the electromagnet is in the first condition, the printhead being retained in one of the first and second configurations by said attractive magnetic force generated between the permanent magnet and the electromagnet.