A light-emitting device includes: a first light- emitting unit that extends in one direction and has a first emission surface located along the one direction, the first emission surface emitting light; a second light-emitting unit that is located in the one direction with respect to the first light-emitting unit, that extends in the one direction, and that has a second emission surface located along the one direction, the second emission surface emitting light; a first cleaning unit that is capable of moving in the one direction and an opposite direction that is opposite to the one direction to clean the first emission surface; a second cleaning unit that is capable of moving in the one direction and the opposite direction to clean the second emission surface; and a transmission unit that extends from the first cleaning unit and the second cleaning unit in the one direction and that transmits a moving force for moving the first cleaning unit and the second cleaning unit to the first cleaning unit and the second cleaning unit.

Method of controlling a laser marking matrix system, the matrix system comprising an N×M matrix of lasers to produce the laser marking, the method comprising the sequential transformation of at least two images to be marked into a series of marking commands according to an N×M matrix of dots, which comprises the following phases: division of a first image into a fixed portion and a variable portion, transformation of the fixed portion into a fixed matrix and the variable portion into a variable matrix, combination of said fixed and variable matrices, laser marking of the first image, processing of a second image, obtaining a new variable matrix which is added to the previous fixed matrix, producing a complete new matrix, laser marking of the second image.

Method of controlling a laser marking matrix system, the matrix system comprising an N×M matrix of lasers to produce the laser marking, the method comprising the sequential transformation of at least two images to be marked into a series of marking commands according to an N×M matrix of dots, which comprises the following phases: division of a first image into a fixed portion and a variable portion, transformation of the fixed portion into a fixed matrix and the variable portion into a variable matrix, combination of said fixed and variable matrices, laser marking of the first image, processing of a second image, obtaining a new variable matrix which is added to the previous fixed matrix, producing a complete new matrix, laser marking of the second image.

To provide a method of manufacturing a light-emitting module capable of accurately arranging a plurality of light-emitting elements at narrow intervals, and a light-emitting module manufactured by the method of manufacturing, and, moreover, a device on which the light-emitting module is mounted. Provided is a method of manufacturing a light-emitting module including: a plurality of light-emitting element arrays each including, in a plane parallel to resonator length of a light-emitting element, a plurality of the light-emitting elements arranged along a width direction perpendicular to a direction of the resonator length; and a substrate on which the plurality of light-emitting element arrays is mounted, the method including arranging the plurality of light-emitting elements on the substrate at predetermined intervals along the width direction in the light-emitting module, by causing side surfaces of the respective light-emitting element arrays adjacent to each other along the width direction to be in contact with each other and mounting the respective light-emitting element arrays on the substrate.

To provide a method of manufacturing a light-emitting module capable of accurately arranging a plurality of light-emitting elements at narrow intervals, and a light-emitting module manufactured by the method of manufacturing, and, moreover, a device on which the light-emitting module is mounted. Provided is a method of manufacturing a light-emitting module including: a plurality of light-emitting element arrays each including, in a plane parallel to resonator length of a light-emitting element, a plurality of the light-emitting elements arranged along a width direction perpendicular to a direction of the resonator length; and a substrate on which the plurality of light-emitting element arrays is mounted, the method including arranging the plurality of light-emitting elements on the substrate at predetermined intervals along the width direction in the light-emitting module, by causing side surfaces of the respective light-emitting element arrays adjacent to each other along the width direction to be in contact with each other and mounting the respective light-emitting element arrays on the substrate.

A light-emitting device includes: a first light-emitting unit that extends in one direction and that has a first emission surface that emits light located along the one direction; a second light-emitting unit that is located in the one direction with respect to the first light-emitting unit, that extends in the one direction, and that has a second emission surface that emits light located along the one direction; a cleaning unit that is capable of moving in the one direction and an opposite direction that is opposite to the one direction to clean the first emission surface; a transmission part that extends from the cleaning unit in the one direction and that transmits a moving force for moving the cleaning unit to the cleaning unit; and an extending part that extends from the transmission part in the one direction to elongate the transmission part. When the cleaning unit is positioned furthest in the opposite direction, an end of the extending part in the one direction is located further in the one direction than a midpoint between an end of the first light-emitting unit in the one direction and an end of the second light-emitting unit in the one direction.

A laser recording device of an embodiment is for a thermal recording medium in which at least one color development layer developing a color through heat and a protective layer protecting recorded information obtained through color development of the at least one color development layer are laminated, and has light transmission properties before recording. The laser recording device includes a recording head in which emitters emitting laser light from laser light sources are arranged, and a recording controller performing parallel processing of control for causing the laser light sources to emit light independently of each other and guiding the laser light from the emitters to the thermal recording medium.

A laser recording device of an embodiment is for a thermal recording medium in which at least one color development layer developing a color through heat and a protective layer protecting recorded information obtained through color development of the at least one color development layer are laminated, and has light transmission properties before recording. The laser recording device includes a recording head in which emitters emitting laser light from laser light sources are arranged, and a recording controller performing parallel processing of control for causing the laser light sources to emit light independently of each other and guiding the laser light from the emitters to the thermal recording medium.

A light-emitting device including: a light-emitting unit extending in one direction; an emission surface that is provided at the light-emitting unit along the one direction, and emits light in a light-emitting direction, the light-emitting direction and the one direction crossing each other; a base that is located in a direction opposite to the light-emitting direction of the light-emitting unit, and on which the light-emitting unit is removably provided; and a cleaning mechanism that includes a cleaning unit cleaning the emission surface by moving along the one direction, the cleaning mechanism allowing the light-emitting unit to be removed from the base while at least a portion of the cleaning mechanism remains on an object other than the light-emitting unit.

A laser imager for a printing system, comprising a plurality of independently addressable surface emitting lasers arranged in a linear array on a common substrate chip and including a common cathode and a dedicated control channel associated with an address trace line for each laser of the plurality of independently addressable surface emitting lasers, and optical elements arranged in a linear lens array configured to capture and focus light from the plurality of independently addressable surface emitting lasers onto a imaging member, wherein the plurality of independently addressable surface emitting lasers arranged in a linear array and the optical elements arranged in a linear lens array operate together to image the imaging member.