A UV inkjet printer includes a UV radiation device to irradiate jetted ink on a receiver, wherein the UV radiation device is attached to an inkjet print head module and includes a UV bulb lamp parallel to a slow scan direction; and the radiation device includes a shutter system to create a first irradiation zone on the receiver and to create a second irradiation zone.

Provided is an image processing apparatus configured to perform by itself image erasing and image recording to a thermally reversible recording medium by irradiating it with laser light and heating it, including a laser light emitting unit, a laser light scanning unit, a focal length control unit, and an information setting unit. During image erasing, the focal length control unit performs control to defocus at the position of the thermally reversible recording medium. During image recording, the focal length control unit performs control to be at a focal length from the position of the thermally reversible recording medium. Immediately after image erasing based on image erasing information set by the information setting unit is completed, image recording is performed based on image recording information.

A device for applying at least a first energy to a substrate includes a conversion material application unit configured to apply a conversion material for converting a second energy to the first energy to the substrate and an energy application unit configured to apply the second energy to the conversion material applied to the substrate, wherein the second energy corresponds to an amount of heat not less than heat of evaporation of the conversion material.

A drawing system according to an embodiment of the present disclosure includes a storage, an operation section, and a drawing section. The storage stores a characteristic function that derives output setting values of light sources on the basis of drawing coordinates, an absorbance correlation value, and gradation values in a leuco color space. The operation section derives the output setting values by inputting, to the characteristic function, the drawing coordinates, gradation values of leuco image data described in the leuco color space, and an absorbance correlation value obtained by measuring the recording medium. The drawing section includes the light sources, and controls output of the light sources on the basis of the output setting values derived by the operation section to thereby perform drawing on the recording medium.

A drawing system according to an embodiment of the present disclosure includes a storage, an operation section, and a drawing section. The storage stores a characteristic function that derives output setting values of light sources on the basis of drawing coordinates, an absorbance correlation value, and gradation values in a leuco color space. The operation section derives the output setting values by inputting, to the characteristic function, the drawing coordinates, gradation values of leuco image data described in the leuco color space, and an absorbance correlation value obtained by measuring the recording medium. The drawing section includes the light sources, and controls output of the light sources on the basis of the output setting values derived by the operation section to thereby perform drawing on the recording medium.

A drawing method according to an embodiment of the present disclosure includes, when performing drawing on a thermal recording medium that includes a light-transmitting member above a recording layer, obtaining information regarding the light-transmitting member, predicting an optical axis deviation of a laser beam in the recording layer from the information regarding the light-transmitting member, and calculating a correction amount from a result of the prediction of the optical axis deviation.

An optical fiber having a coating that includes a photoreactive marking compound is described. The photoreactive marking compound has two states that differ in the intensity and/or wavelength of fluorescence. Exposure of the photoreactive marking compound to electromagnetic radiation induces a transformation of the photoreactive marking compound from one state to the other state. The difference in fluorescence between the two states provides a detectable contrast that can be used to mark the optical fiber. A pattern of marks can be customized to different optical fibers to provide unambiguous identification of individual fibers. The coating may also include a pigment, where either or both of the pigment and photoreactive marking compound may function as a marker for identifying the optical fiber. The method extends generally to marking of films, coatings, and articles made of polymers or plastics.

An optical fiber having a coating that includes a photoreactive marking compound is described. The photoreactive marking compound has two states that differ in the intensity and/or wavelength of fluorescence. Exposure of the photoreactive marking compound to electromagnetic radiation induces a transformation of the photoreactive marking compound from one state to the other state. The difference in fluorescence between the two states provides a detectable contrast that can be used to mark the optical fiber. A pattern of marks can be customized to different optical fibers to provide unambiguous identification of individual fibers. The coating may also include a pigment, where either or both of the pigment and photoreactive marking compound may function as a marker for identifying the optical fiber. The method extends generally to marking of films, coatings, and articles made of polymers or plastics.

There is provided a light irradiator including: light sources forming first and second light source rows; a heat sink; a substrate including first and second traces connected to the first and second light source rows, respectively; and a fixing part configured to fix the heat sink to the substrate. The fixing part is arranged between adjacent light sources included in the first light source row and adjacent in the first light source row; and the fixing part is not arranged between adjacent light sources included in the second light source row and adjacent in the second light source row. The first trace includes a first circumventing part configured to circumvent the fixing part; and the second trace includes a second circumventing part configured to circumvent the fixing part and having a directional component different from the first direction.

A substrate can be positioned for coating by a deposition device. The deposition device can coat the substrate with photosensitive material. The coated substrate can be positioned for exposure to light from a light source. The light source can expose a portion of the coated substrate to light to produce printed information.