JP2006058557A - Laser exposure apparatus - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a laser exposure apparatus with which a variation in the reflectance in a main scanning direction on the reflection face of a polygon mirror is corrected when forming a color image by scanning and exposing a photosensitive material with laser light. <P>SOLUTION: The laser exposure apparatus comprises: a first, a second and a third color laser light sources 20R, G and B for exposing and forming an image on the photosensitive material; a polygon mirror 26 for scanning and exposing with the laser beams in a main scanning direction; a reflection face recognition means 34 which recognizes the positions of respective reflection faces on the basis of recognition signals for recognizing the respective reflection faces of the polygon mirror 26; a correction data storing means 36 which independently stores shading correction data with which the variation in reflectance on a reflection face and among respective reflection faces is corrected for respective reflection faces and respective colors; a correction data selection means 39 which selects the correction data stored in the correction data storing means 36 for the respective colors on the basis of the recognized result by the reflection face recognition means 34; and acousto-optical elements 21R, G and B which correct the image data for respective colors on the basis of selected correction data and optically modifies the laser beams on the basis of the corrected image data. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention scans and exposes a laser light source that outputs laser light of each of the first, second, and third colors to form a color image, and laser light that is light-modulated based on image data in the main scanning direction. The present invention relates to a laser exposure apparatus provided with a polygon mirror for the purpose.

  Such a laser exposure apparatus is used to create a photographic print by scanning a photographic photosensitive material with a light-modulated laser beam to print and expose an image. In order to form a color image, laser light sources of three colors of a first color (R), a second color (G), and a third color (B) are used. Laser light output from each laser light source is light-modulated based on image data by an acousto-optic element (corresponding to light modulation means). The light-modulated laser light is introduced into a scanning optical system for scanning the laser light along the main scanning direction. The scanning optical system includes a polygon mirror and an fθ lens, and the laser light is guided to the emulsion surface of the photographic material. The photographic light-sensitive material is transported by a transport mechanism along the sub-scanning direction, and a latent image can be formed on the emulsion surface by repeatedly scanning laser light along the main scanning direction with a scanning optical system. The photographic light-sensitive material on which the latent image is formed is sent to the development processing unit, where the development processing is performed to reveal the latent image and create a photographic print.

  In the laser exposure apparatus described above, the polygon mirror includes a large number of reflecting surfaces along the circumferential direction, and is configured to be rotatable around a predetermined axis. The laser beam is scanned in the main scanning direction by rotating the reflecting surface. Therefore, if the reflectance characteristics of the plurality of reflecting surfaces are not the same for all three colors, the formed image may be uneven and the image quality may be degraded. Further, not only the difference in reflectance characteristics between different reflecting surfaces, but also unevenness in reflectance may exist within the same reflecting surface, and such unevenness in reflectance also causes deterioration in image quality. In order to make the reflectance characteristics of all the reflecting surfaces of the polygon mirror uniform, there is a problem that expensive processing such as multi-coating is required and the cost of the apparatus is increased.

  As a technique paying attention to the difference in characteristics of the reflection surface of the polygon mirror, there is a scanning optical device disclosed in Patent Document 1 below. This device outputs an index signal each time a specific reflecting surface of a plurality of reflecting surfaces of a polygon mirror passes a specific rotational position, and reads error information on the reflecting surface based on the index signal. Correction means for controlling the luminous flux so as to correct the above. The correcting means corrects the angle of the light beam for each reflecting surface so as to cancel the position error due to the shape error of the reflecting surface. Specifically, the correcting means includes a dynamic prism disposed in the optical path. Is turned to change the declination action. Such a configuration requires a driving mechanism for driving the prism and requires extremely precise driving. Therefore, even if the variation in reflectance characteristics can be suppressed, there is a possibility that the mechanism becomes an expensive mechanism. In addition, since the reflectance characteristics vary depending on the wavelength of the laser beam, when forming a color image, it is necessary to individually correct for the three colors of laser beam, but in the configuration where a prism is arranged in the optical path, Difficult to individually correct.

On the other hand, there is a thermal recording apparatus having a shading correction function disclosed in Patent Document 2 below. This apparatus forms an image by irradiating a heat-sensitive recording material with a laser beam, and scans the laser beam in a main scanning direction by a light deflecting means (polygon mirror or the like) to form an image. A storage unit for holding shading correction data for correcting the transmission rate of the laser beam to the heat-sensitive recording material by the light deflection unit is provided, and the output of the laser beam generation unit and / or the remaining heat unit is corrected by the shading correction data. The remaining heat means has a function of applying heat to the heat-sensitive recording paper. However, when the emulsion surface of the photographic light-sensitive material is exposed, there is a possibility that the photosensitive characteristics may be changed if heat is applied. Patent Document 2 does not mention the relationship between each reflecting surface and shading correction data. That is, since the shading correction data is different for each reflection surface, it is necessary to control the shading correction data to be read out in accordance with the rotational position of the reflection surface in the polygon mirror, but there is no disclosure regarding such control. Further, Patent Document 2 discloses an embodiment having only one laser light source, and there is no mention of shading correction data when a color image is formed. In the case of forming a color image, three colors of laser light are required, and the reflectance characteristics differ depending on the wavelength, and it is necessary to perform shading correction in consideration of this.
JP-A-9-212370 (Claims) Japanese Patent Laid-Open No. 6-218976 (Claims, FIG. 1, FIG. 4, etc.)

  The present invention has been made in view of the above circumstances, and the problem is that when forming a color image by scanning and exposing a photographic photosensitive material with a laser beam, a variation in the reflectance in the main scanning direction on the reflecting surface of the polygon mirror. It is to provide a laser exposure apparatus capable of correcting the above.

In order to solve the above problems, a laser exposure apparatus according to the present invention comprises:
A laser light source that outputs laser light of each of the first color, the second color, and the third color in order to expose and form a color image on the emulsion surface of the photographic material;
A laser exposure apparatus comprising a polygon mirror for scanning and exposing a laser beam light-modulated based on image data in a main scanning direction,
Reflection surface recognition means for recognizing the position of each reflection surface based on an identification signal for identifying each reflection surface constituting the polygon mirror;
Correction data storage means for storing shading correction data for correcting variations in reflectance in the main scanning direction in the reflection surface and variations in reflectance between the reflection surfaces for each reflection surface and for each color individually When,
Correction data selection means for selecting and outputting the shading correction data stored in the correction data storage means for each color based on the result recognized by the reflection surface recognition means;
Based on the selected shading correction data, image data correction means for correcting and outputting image data for each color, and
And a light modulation means for performing light modulation of the laser beam based on the corrected image data.

  The operation and effect of the laser exposure apparatus having such a configuration will be described. A laser light source that outputs laser beams of the first color, the second color, and the third color is provided, and a color image can be formed by exposure on the emulsion surface of the photographic light-sensitive material. A polygon mirror is provided for main scanning with laser light. In addition, an identification signal for identifying each reflection surface of the polygon mirror can be output, and the position of each reflection surface can be recognized based on this identification signal. Further, shading correction data for correcting the variation in reflectance within the reflecting surface and the variation in reflectance between the reflecting surfaces is stored in the correction data storage means. Such shading correction data can be acquired in advance. Further, the shading correction data is separately obtained and stored for each color. When the laser beam is actually scanned, shading correction data corresponding to the recognized reflection surface is selected and output for each color based on the result recognized by the reflection surface recognition means. Based on the output correction data, the image data is corrected for each color, and the laser light is modulated based on the corrected image data.

  By providing the function of the reflection surface recognition means, it is possible to select shading correction data suitable for each reflection surface, and to perform accurate correction. Further, the shading correction data is stored for each color, and the shading correction corresponding to the color image can be appropriately performed. Further, the image data is corrected, and a complicated drive mechanism is not required, which is advantageous in terms of cost. As a result, it is possible to provide a laser exposure apparatus capable of correcting variations in reflectance in the main scanning direction on the reflecting surface of a polygon mirror when a photographic photosensitive material is scanned and exposed to laser light to form a color image. .

  A preferred embodiment of a photographic processing apparatus in which a laser exposure apparatus according to the present invention is used will be described with reference to the drawings. FIG. 1 is a schematic diagram showing a configuration of a photographic processing apparatus.

<Configuration of photo processing apparatus>
This photographic processing apparatus has a function of reading a frame image formed on a photographic film such as a negative film and creating a photographic print. It also has a function of reading image data stored in a media medium and creating a photographic print.

  The film scanner 1 reads a frame image formed on a developed photographic film and converts it into digital data. The media image input unit 2 has a function of taking in image data stored in a storage medium of a digital camera, an MO disk, a CD-R, or the like. The image data storage unit 3 stores the image data acquired by the film scanner 1 or the media image input unit 2. The image processing unit 4 performs image processing on the acquired original image data, and generates print image data for creating a photographic print. Image processing includes color / density correction, red-eye correction, backlight correction, image enlargement processing, trimming, and the like to make the color / density appropriate. The image data subjected to the image processing is transferred to a laser exposure device 8 to be described later via the image transfer unit 5.

  The paper magazine 6 contains paper (photographic photosensitive material) in the form of a roll R. The paper drawn out from the paper magazine 6 is transported along a predetermined transport path. The paper cutter 7 cuts the drawn paper into a predetermined print size. The cut paper is transported to the laser exposure device 8 by a transport mechanism. The laser exposure device 8 includes a laser engine 9 and an exposure transport roller 10 for transporting paper at a constant speed. The laser engine 9 performs scanning exposure with a laser beam based on the image data transferred from the image transfer unit 5, and exposes and forms an image on the emulsion surface of the paper.

  The paper on which the image has been printed and exposed is subjected to development processing and drying processing in the development processing section 11 and the drying processing section 12, respectively, and is then discharged as a photographic print to the outside of the apparatus.

<Configuration of laser exposure apparatus>
Next, the configuration of the laser exposure apparatus 8 will be described with reference to FIG. Three laser light sources 20R, 20G, and 20B for the three primary colors are provided at appropriate positions on the light-shielded casing. The laser light source 20R is configured by a semiconductor laser (LD) that emits R (first color = red) laser light having a wavelength of 680 nm, for example. The laser light source 20G includes a semiconductor laser and a second harmonic generator (SHG) that converts laser light emitted from the semiconductor laser into G (second color = green) laser light having a wavelength of 532 nm, for example. . The laser light source 20B includes a semiconductor laser and a second harmonic generator (SHG) that converts laser light emitted from the semiconductor laser into, for example, 473 nm B (third color = blue) laser light.

  On the output side of each of the laser light sources 20R, 20G, and 20B, AOM (acousto-optic elements) 21R, 21G, and 21B, which are examples of light modulation means, and slits 22R, 22G formed at appropriate positions in the light shielding casing, 22B are respectively arranged correspondingly, and the mirrors 23R, 23G, 23B, the reflecting mirror 24, the lens 25, and the lens 25 constituting the scanning optical system are rotated in the S direction in FIG. A polygon mirror 26 that scans in the direction (main scan) is sequentially arranged.

  The AOM drivers 27R, 27G, and 27B drive and control the AOMs 21R, 21G, and 21B based on the image data, and optically modulate the laser light. The AOMs 21R, 21G, and 21B can adjust the output of laser light within a range of approximately 100% to 0%.

  The mirror 23R is a total reflection mirror, and the mirrors 23G and 23B are half mirrors. In the above arrangement, the laser light emitted from the AOM 21R is totally reflected by the mirror 23R, and the laser light emitted from the AOM 21G and the mirror 23G are combined. Thereafter, the laser light emitted from the AOM 21B and the mirror 23B are further combined to combine the three colors of laser light.

  An fθ lens 30 is disposed on the exit side of the polygon mirror 26. The polygon mirror 26 rotates in the direction of the arrow S, and the laser beam scanned in the main scanning direction (Q direction) by this rotation passes through the fθ lens 30 and is being conveyed in the sub-scanning direction (direction perpendicular to the paper surface). The paper P is irradiated and the paper P is exposed. Further, a mirror 28 is disposed on the exit side of the fθ lens 30 and immediately upstream of the image exposure region, and a synchronization sensor 29 including a light receiving element that receives reflected light from the mirror 28 is disposed. Yes. The synchronization sensor 29 is configured by arranging three light receiving elements that receive R, G, and B laser beams. When the light receiving element detects the laser beam of the corresponding color, it outputs a detection signal to the control unit.

  The polygon mirror 26 has a regular hexagonal shape in plan view and has six reflecting surfaces. Various modifications of the shape of the polygon mirror 26 are conceivable, and the polygon mirror 26 may not be a regular hexagon, and the number of reflecting surfaces such as a regular octagon may be changed. The polygon mirror 26 is rotationally driven by a pulse motor 32, and a drive circuit 33 for that purpose is provided. The drive circuit 33 drives the pulse motor by supplying a drive pulse to the pulse motor 32.

  Of the six reflecting surfaces of the polygon mirror 26, an identification mark 26b is attached to detect a specific reflecting surface. Reflecting surface recognition means 34 is provided for recognizing each reflecting surface based on the identification mark 26b. The reflection surface recognition unit 34 includes an optical sensor 34a and can detect a specific reflection surface. Further, the reflection surface recognition means 34 can also recognize other reflection surfaces with reference to the signal obtained by detecting the identification mark 26b. For example, it is possible to obtain a drive pulse signal for driving the pulse motor 32 from the drive circuit 33 and to recognize all the reflection surfaces based on this signal and the signal from the identification mark 26b. Therefore, it can be understood which reflecting surface is currently used for the main scanning of the laser beam.

  The image data storage unit 3 stores image data acquired from the film scanner 1 or the like as already described. The image data stored in the image data storage unit 3 is subjected to image processing by the image processing unit 4 and then transferred to the laser exposure apparatus 8 via the image transfer unit 5. The image transfer unit 5 includes buffer memory units 5R, 5G, and 5B for each color, and image data is temporarily stored in the buffer memory units 5R, 5G, and 5B.

  The shading correction unit 35 reads the shading correction data from the correction data storage unit 36 and corrects the image data. Shading correction is performed separately for each color of image data. Accordingly, an R shading correction unit 35R, a G shading correction unit 35G, and a B shading correction unit 35B are provided. Details of the shading correction will be described later. The shading-corrected image data of each color is A / D converted by the D / A conversion circuits 31R, 31G, and 31B for each color, and then transmitted to the AOM drivers 27R, 27G, and 27B. Thereby, the laser beam can be optically modulated according to the image data.

<Configuration of shading correction unit>
Next, the configuration of the shading correction unit 35 will be described. In order to form a color image, the image data of one image is composed of image data for three colors. Shading correction is also performed independently for each color, but shading correction for three colors is performed simultaneously in parallel, and the configuration for performing shading correction is the same for each color. FIG. 3 shows only the configuration of the shading correction unit for one color for convenience.

  The correction data storage means 36 is a storage device composed of a hard disk or the like, and stores shading correction data. As shown in FIG. 3, shading correction data for each reflecting surface of the polygon mirror 26 is stored. Such shading correction data can be acquired in advance in an inspection process or the like. In this embodiment, since the polygon mirror 26 has six reflecting surfaces, shading correction data is also acquired for each reflecting surface, and data is stored for the reference surface, A, B, C, D, and E surfaces. .

  FIG. 4 shows each reflecting surface, and the identification mark 26b is given to the reference surface. Starting from the reference plane, there are A plane, B plane, C plane, D plane, and E plane in the clockwise direction. A direction corresponding to the main scanning direction is indicated by an arrow T in FIG. The same applies to other reflecting surfaces on which the arrow T is not drawn. The shading correction corrects the variation in reflectance among the six reflecting surfaces and also corrects the variation (unevenness) in reflectance on one reflecting surface. In FIG. 4, the reflectances must be the same along the direction of the arrow T. However, since there is actually unevenness, the reflectances are not the same. Therefore, such variations are also corrected.

  Further, since the variation in reflectance differs for each color, shading correction data is also prepared for each color. Although only shading correction data for one color is shown in FIG. 3, there are actually three colors. For example, the A-side shading correction data is prepared for three colors for R, G, and B. The shading correction data can be stored in the form of table data, for example.

  The shading correction data selection signal generation circuit 37 generates a signal as to whether shading correction data for the surface should be selected based on the recognition signal from the reflection surface recognition means 34 and the signal from the clock generation circuit 38. The clock generation circuit 38 generates a synchronization signal for timing. The correction data selection circuit 39 (corresponding to correction data selection means) selects shading correction data for any one surface based on the selection signal from the shading correction data selection signal generation circuit 37.

  The image data correction unit 40 has a function of correcting the image data using the selected shading correction data. Image data in the image transfer unit 5 is read and shading correction is performed. The corrected image data is sent to the D / A conversion circuit 31 via the image data output means 41 and D / A converted. Thereby, the laser beam can be optically modulated by the image data corrected for shading.

<Another embodiment>
The laser light source used in the laser exposure apparatus is not limited to a specific type of light source. In the present embodiment, AOM is exemplified as the light modulation means, but the present invention is not limited to this. Further, instead of an external modulation unit such as AOM, a light modulation unit based on a direct modulation method in which a laser light source is directly turned on / off may be used.

  The method for obtaining the identification signal is not limited to this embodiment. Instead of the identification mark, a protrusion may be provided at the position of a specific reflecting surface, and this may be detected. The configuration of the identification mark can be determined as appropriate. For example, a sticker with a high reflectance may be pasted or a barcode may be pasted.

  In the present embodiment, the variation in reflectance has been described. However, the surface tilt of the polygon mirror can be similarly corrected by the shading correction data.

Schematic diagram showing the configuration of the photo processing device Schematic diagram showing the configuration of the laser exposure apparatus Schematic diagram showing the configuration of the shading correction unit Diagram showing polygon mirror

Explanation of symbols

5 Image transfer unit 8 Laser exposure device 9 Laser engine 20R, 20G, 20B Laser light source 21R, 21G, 21B AOM (acousto-optic device)
22R, 22G, 22B Slit 23R, 23G, 23B Mirror 26 Polygon mirror 26b Identification mark 27R, 27G, 27B AOM drivers 31R, 31G, 31B D / A conversion means 32 Pulse motor 33 Drive circuit 34 Reflecting surface recognition means 35 Shading correction section 36 correction data storage means 37 shading correction data selection signal generation circuit 39 correction data selection circuit 40 image data correction means 41 image data output means

Claims (1)

A laser light source that outputs laser light of each of the first color, the second color, and the third color in order to expose and form a color image on the emulsion surface of the photographic material;
A laser exposure apparatus comprising a polygon mirror for scanning and exposing a laser beam light-modulated based on image data in a main scanning direction,
Reflection surface recognition means for recognizing the position of each reflection surface based on an identification signal for identifying each reflection surface constituting the polygon mirror;
Correction data storage means for storing shading correction data for correcting the variation in reflectance in the main scanning direction within the reflecting surface and the variation in reflectance between the reflecting surfaces individually for each reflecting surface and for each color When,
Correction data selection means for selecting and outputting the shading correction data stored in the correction data storage means for each color based on the result recognized by the reflection surface recognition means;
Based on the selected shading correction data, image data correction means for correcting and outputting image data for each color, and
A laser exposure apparatus comprising: light modulation means for performing light modulation of laser light based on the corrected image data.

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