JP4409249B2 - Printing plate creation data generation method and apparatus, printing plate creation data generation program, and computer-readable recording medium recording the program - Google Patents

Description

  The present invention relates to a printing plate creation data generation method and apparatus, a printing plate creation data generation program, and a computer-readable recording medium on which the program is recorded.

  A plurality of print images respectively corresponding to a plurality of print images (for example, print images of a plurality of different basic colors such as cyan (C), magenta (M), yellow (Y), and black (K)). In a printing machine (for example, a multicolor printing machine) that sequentially prints a plurality of print images on a printing medium (for example, printing paper) using a plate, generally, ink or ink and water are applied to each printing plate. The ink is sequentially transferred from each printing plate supplied and supplied with the ink or the like to a printing medium conveyed in a predetermined conveyance direction, whereby a printed image (for example, a multicolor printing image) is printed on the printing medium. Is printed. At this time, each print image printed by each printing plate is printed so that the printing position matches on the printing medium.

In the field of printing technology using such a printing plate, in recent years, CTP (Computer To Plate) printing, in which a printing plate is directly created and printed based on printing data corresponding to a print image, has attracted attention. Yes. As a printing method of this CTP printing, for example,
(A) A page description of print data (for example, PostScript (registered trademark) of Adobe Systems, etc.) corresponding to a print image using a print data creation device (for example, a computer equipped with layout editing software). (Print data in PDL: Page Description Language) is created, and the created print data is loaded into a print plate creation data generator (for example, RIP (Raster Image Processor) or a computer with software RIP) To the printing plate creation data (for example, raster data rasterized in bitmap), and the converted printing plate creation data is binarized (for example, halftone), Further, based on the binarized (for example, halftone dot and halftone developed) printing plate creation data, a printing plate creating apparatus is used to print the printing plate. And printing on the substrate by providing the printing plate created in this way on the printing machine,
(B) As described in (a) above, using the printing data creation device, print data corresponding to the print image is created, and printing plate creation data is generated based on the created print data. Using the apparatus to generate binarized printing plate creation data, and further, based on the binarized printing plate creation data, a printing machine equipped with a printing plate creation device (more specifically, printing An example is a case in which a printing plate is created using an on-press type DI (Direct Imaging) printing machine capable of creating a plate in the machine, and printing is performed on the printing medium using the created printing plate.

  In any case, when printing is performed with a printing machine (for example, a multicolor printing machine) using a plurality of printing plates, the quality (type, size, thickness) and printing of the printing medium (for example, printing paper) Depending on the printing conditions such as the pressure applied to the printing medium at the time of printing or the amount of water to be used, the printing medium may be deformed due to expansion and contraction (usually a rectangular shape is deformed in a shape close to a trapezoidal shape). Therefore, for example, a phenomenon may occur in which the positions of the preprinted print image and the postprinted print image are not aligned, and the positions of the print images C, M, Y, and K are shifted. Note that this effect is further increased as the number of images increases.

  In order to solve such a problem, in the conventional CTP printing, conventionally, in the case of (a), for example, as shown in FIG. Is provided with a device 30 for correcting the imaging device 41 that forms an image corresponding to the print image, and based on the print data created by the print data creation device 10, a printing plate creation data generation device (for example, RIP) 20 ′. After generating the printing plate creation data binarized at, for example, RIP, a plurality of printing plates are created by the printing plate creation device 40 based on the generated printing plate creation binary data. When Ac ′, Am ′, Ay ′, and Ak ′ are sequentially created, the image position (that is, printing onto the printing plate) when each printing plate is created by controlling the imaging device 41 by the device 30 described above. It is doing the correction of position). In the case of (b), for example, as shown in FIG. 7 (B), the printing plate making apparatuses 40c, 40m, 40y, and 40k are each provided with a device 30 for correcting the imaging device 41 for printing. After generating the printing plate creation data binarized by the printing plate creation data generation device (for example, RIP) 20 ′ based on the printing data created by the data creation device 10, for example, RIP expanded Based on the generated binarized data for creating a printing plate, a plurality of printing plates Ac ′, Am ′, Ay ′, and a plurality of printing plate creating devices 40c, 40m, 40y, 40k of the DI printing machine 50 ′. When creating each Ak ′, the image position (that is, each dot on the printing plate) when each printing plate is created by controlling each imaging device 41 by each device 30 described above. Correction is performed in the pixel) printing position) (for example, see Patent Document 1, 5, 6, 7).

  However, in the printing method for correcting the printing position of the binarized data for printing plate creation after the binarization, for example, RIP development as described above, on the printing plate as described above, the imaging apparatus in the printing plate making apparatus Therefore, it is necessary to provide a correction device for each imaging device, and an extra device is required as compared with the prior art, leading to an increase in the cost of the device. Further, by correcting the image position when creating the printing plate for the printing plate creation data after RIP development, the dots (pixels) of the imaging originally composed of the printing plate creation data are connected. This results in a decrease in print quality due to image position correction when creating a printing plate, such as when something is missing.

  Therefore, a printing method has been proposed in which position correction is performed when creating printing data to be processed in a printing data creation apparatus (a computer equipped with imposition software or the like) as shown in FIG. (For example, see Patent Documents 2, 3, and 4).

  However, for example, the printed material is exaggerated in FIG. 8 by being conveyed while being squeezed between each cylinder such as an impression cylinder or a rubber cylinder while the leading end is sandwiched in printing. As described above, the printing medium (for example, printing paper Q) is gradually extended in the direction (Y direction in the figure) across the conveyance direction X from the most downstream side to the most upstream side in the conveyance direction (X direction in the figure) (as in the illustrated example). A trapezoidal shape) (so-called fan-out) may occur, and this phenomenon tends to become more prominent when printing is repeated, and the positions of the printed images C, M, Y, and K are shifted accordingly. End up. In this case, the amount of elongation M of the printing medium (for example, printing paper Q) differs between the most downstream side and the most upstream side in the transport direction X, and when printing data is processed that is processed in the printing data generating apparatus as described above. In the conventional printing method for correcting the position in the above, the problem that the fanout occurs is only considered in a certain group unit (page unit). The fact is that it has not been taken into account, so it cannot be handled accurately. In FIG. 8, M indicates the amount of elongation during black image printing.

  The present invention has been made in view of the above problems, and when performing CTP printing, it is necessary to provide a correction apparatus for each imaging apparatus without controlling the position correction of the imaging apparatus in the printing plate making apparatus. In addition, the cost of the apparatus can be reduced by that amount, and the printing plate creation can be performed without correcting the image position when creating the printing plate for binarized (for example, network development) printing plate creation data. The print quality can be prevented from being deteriorated due to the image position correction at the time of printing, and further, it gradually extends in the direction crossing the transport direction from the most downstream side to the most upstream side in the transport direction of the printing medium (extends in a trapezoidal shape, etc. ) Regardless of the phenomenon, so-called fan-out, the printing plate can be accurately aligned with the pre-printed print image and the post-printed print image. And to provide a computer readable recording medium recording a data generation method and printing plate making data generating apparatus and the printing plate creation data generation program and the printing plate creation data generation program.

JP-T-6-507353 (Patent No. 3091489) Japanese Patent Laid-Open No. 9-109356 (Japanese Patent No. 3303628) JP-A-9-258424 JP-A-9-323471 JP 2002-29032 A JP 2002-67268 A JP 2002-361817 A

  In order to solve the above problems, the present invention provides the following printing plate creation data generation method, printing plate creation data generation device, printing plate creation data generation program, and recording medium.

(1) Printing plate creation data generation method A plurality of print images (for example, a plurality of different basic colors such as cyan (C), magenta (M), yellow (Y), and black (K)) When printing a plurality of print images on a printing medium using a plurality of printing plates respectively corresponding to (print images) (for example, when printing with a multicolor printing machine), to create the plurality of printing plates The printing plate creation data is generated in the printing medium when each printing is performed for each printing of the plurality of print images on the printing body by the plurality of printing plates ( A storage step for storing in advance correction values for the amount of expansion / contraction in the direction to be expanded / contracted (at a plurality of points indicating the shape of deformation of the printing body), and printing data corresponding to the plurality of print images Multi-value A conversion step for converting to data, and the multi-value data for printing plate creation converted in the conversion step, in the direction to be expanded or contracted based on the correction value stored in advance in the storage step A correction step for performing expansion / contraction correction in a corresponding direction, and a binarization process for converting the printing plate creation multi-value data subjected to the expansion / contraction correction in the correction step into halftone dot printing plate creation binary data In the storing step, for each printing of the plurality of print images on the printing medium by the plurality of printing plates, a predetermined first direction on the printing medium when each printing is performed Correction values for expansion / contraction amounts to be expanded / contracted in a predetermined second direction crossing the first direction with respect to a plurality of positions along the line are stored in advance, and in the conversion step, the plurality of print images are stored. As for the printing data corresponding to, a line of pixels arranged in parallel along a second 'direction corresponding to the second direction is a plurality of lines along a first' direction corresponding to the first direction. In the correction step, the multi-value data for printing plate creation converted in the conversion step is stored in the storage step corresponding to each line. A printing plate creation data generation method, comprising: performing expansion / contraction correction in the second ′ direction on the line based on the correction value stored in advance .

(2) Printing plate creation data generating device A plurality of print images (for example, a plurality of different basic colors such as cyan (C), magenta (M), yellow (Y) and black (K)). When printing a plurality of print images on a printing medium using a plurality of printing plates respectively corresponding to (print images) (for example, when printing with a multicolor printing machine), to create the plurality of printing plates The printing plate creation data is generated by the expansion and contraction in the printing medium when each printing is performed on each printing of the plurality of print images on the printing medium by the plurality of printing plates. A storage means for preliminarily storing correction values for the amount of expansion / contraction in the direction to be performed; a conversion means for converting print data corresponding to the plurality of print images into multi-value data for creating a printing plate; and the conversion means. Correction means for performing expansion / contraction correction in a direction corresponding to the direction to be expanded / contracted based on the correction value stored in advance in the storage unit for the converted multi-value data for printing plate creation; Binarization processing means for converting the printing plate making multi-value data subjected to expansion and contraction correction by the correcting means into halftone dot printing plate making binary data, and the storage means Predetermining across the first direction with respect to a plurality of positions along a predetermined first direction on the printing medium when each printing is performed, for each printing of the plurality of printed images on the printing medium by a printing plate The correction value for the expansion / contraction amount to be expanded / contracted in the second direction is stored in advance, and the conversion means stores the second ′ corresponding to the second direction for the print data corresponding to the plurality of print images. In the direction A line of pixels arranged in parallel along the first pixel is converted into multi-value data for printing plate creation consisting of pixel data arranged in a plurality of lines along a first ′ direction corresponding to the first direction. The second-direction in the line based on the correction value stored in advance in the storage unit corresponding to each line for the multi-value data for printing plate creation converted by the conversion unit A data generation apparatus for creating a printing plate , wherein the expansion / contraction correction is performed .

(3) Printing plate creation data generation program A printing plate creation data generation program for causing a computer to execute each step of the printing plate creation data generation method according to the present invention.

(4) Recording medium A computer-readable recording medium in which the printing plate creating data generation program according to the present invention is recorded.

  As the printing data used in the printing plate creation data generation method, the printing plate creation data generation device, the printing plate creation data generation program, and the recording medium according to the present invention, a printing data creation device in CTP printing (for example, Printing data created by a computer equipped with layout editing software), typically, printing data in a page description language such as PostScript (registered trademark) of Adobe Systems.

  In the printing plate creation data generation method, the printing plate creation data generation device, the printing plate creation data generation program, and the recording medium according to the present invention, after the expansion / contraction correction processing is performed in the correction step and the correction unit, the binary (For example, halftone dot processing).

  Printing plate generation data generation method, printing plate generation data generation apparatus, printing plate generation data generation program and printing medium generated in the recording medium and binarized (for example, halftone) processing according to the present invention The binarized data is processed by, for example, a printing plate creation device in CTP printing, a printing plate creation device provided in an on-press type DI printing machine that creates a plate in a printing machine, and binarization for printing plate creation. A plurality of printing plates are created based on the data. In the printing plate making apparatus, the printing plate is made, for example, on an unmade printing plate or plate making film on the basis of the binarized data for making the printing plate with a laser beam or the like in a predetermined sub-scanning direction and the This is done by scanning in the main scanning direction across the sub-scanning direction.

  As described above, in the printing plate creation data generation method, the printing plate creation data generation device, the printing plate creation data generation program, and the recording medium according to the present invention, the printing plate creation device and the DI printing machine for CTP printing are provided. Prior to the creation of the printing plate by the plate making apparatus, the expansion / contraction correction of the printing plate making data is performed, so that it is not necessary to control the position correction of the imaging device in the printing plate making apparatus. Therefore, it is not necessary to provide a correction device for each imaging device, and the device cost can be reduced accordingly. Prior to the binarization processing of the printing plate creation data, the printing plate creation data is subjected to expansion / contraction correction and binarization processing is performed. Therefore, the binarized printing plate creation binarization data is printed. It is not necessary to correct the image position when creating the plate. Therefore, it is possible to prevent a decrease in print quality due to image position correction at the time of creating a printing plate.

  In the correction step and the correction unit, the correction value stored in advance in the conversion step and the storage unit for the printing plate creation data converted in the conversion step and the conversion unit. Based on this, the expansion / contraction correction in the direction corresponding to the direction to be expanded / contracted is performed. Even so, by performing correction that extends in the direction across the transport direction from the most downstream side to the most upstream side in the transport direction of the substrate to be printed, the positions of the pre-printed print image and the post-printed print image can be accurately aligned. Can do.

  In the printing plate creation data generation method and apparatus according to the present invention, in the storage step and the storage unit, each printing is performed for each printing of the plurality of print images on the substrate by the plurality of printing plates. Correction values for the amount of expansion / contraction to be expanded / contracted in a predetermined second direction crossing the first direction with respect to a plurality of positions along the predetermined first direction on the printing medium at the time of being made are stored in advance, and the converting step In the conversion means, for the print data corresponding to the plurality of print images, a line of pixels arranged in parallel along a second ′ direction corresponding to the second direction has a line of pixels arranged in the first direction. The print data is converted into multi-value data for creating a printing plate made up of pixel data arranged in a plurality of lines along the corresponding first 1 'direction. For the printing plate making multi-value data converted by the step and the conversion means, based on the correction value stored in advance in the storage step and the storage means corresponding to each line, The case where the expansion / contraction correction in the second ′ direction is performed can be exemplified. In this case, for example, the first ′ direction of the printing plate preparation data is the sub-scanning direction of the scanning of the laser beam, and the second ′ direction of the printing plate preparation data is the scanning of the laser beam or the like. The main scanning direction can be set.

  In this case, in the printing plate making data generation method and apparatus according to the present invention, as a specific aspect of the expansion / contraction correction performed by the correction step and the correction unit, for example, the conversion step and the conversion unit perform conversion. When the correction value corresponding to each line is the correction value for the elongation amount of the printed multi-value data for creating a printing plate, the correction value for the elongation amount is increased along the second 'direction in the line from the correction value for the elongation amount. The number of pixels is calculated and the number of pixels to be increased is equally or substantially evenly inserted in the line. At this time, the value of the pixel data to be inserted is neighboring pixel data adjacent to the second position in the insertion position. On the other hand, when the correction value corresponding to each line is a correction value for the contraction amount, the correction value for the contraction amount is determined. The reduced pixel and calculates the number of pixels to reduce along the second 'directions can be given if the processing of extracting equally or substantially equally in the line in Luo the line. In this way, it is possible to perform expansion / contraction correction while substantially maintaining the original print image. When the correction value corresponding to each line is a correction value for the expansion amount, the value of the pixel data to be inserted is one pixel data adjacent in the second ′ direction of the insertion position. It is preferable to set one of the values of the other pixel data from the value of. For example, an average value of the value of the one pixel data and the value of the other pixel data can be given.

  In the storage step and the storage means, the correction values stored in advance include a plurality of positions along the first direction on the printing medium when each printing is performed, and the printing plate creation data A correction value for the amount of expansion / contraction to be expanded / contracted in the second direction with respect to a plurality of positions corresponding to the plurality of lines can be exemplified. Further, for example, when the printing medium is conveyed in a predetermined conveyance direction (the first direction), the printing medium is conveyed from the most downstream side in the conveyance direction (the first direction) when each printing is performed. When the expansion / contraction form of the printing medium is specified such that the printing medium gradually extends (extends in a trapezoidal shape) in the direction (second direction) crossing the transport direction (the first direction) toward the upstream side. The correction values stored in advance are a plurality of positions along the first direction on the printing medium when each printing is performed, and a smaller number of lines than a plurality of lines of the printing plate creation data (For example, the first direction in the first direction corresponding to the transport direction (the first direction) and the two lines of the most downstream line and the most upstream line) expand and contract in the second direction with respect to a plurality of positions. Compensation for power It may be a value. By doing so, the storage capacity stored in the storage step and the storage means can be reduced.

  Further, the correction value stored in advance in the storage step and the storage means, for example, is obtained by dividing the expansion / contraction amount by a normal (in other words, before printing) dimension in the second direction of the printing medium. It can be a value (that is, expansion / contraction rate). In any case, the correction value is obtained by, for example, performing a test print using a printing medium to be used for printing, and is obtained by visual inspection and manually input and stored for the print medium subjected to the test printing. Alternatively, it may be obtained by using a predetermined correction value detection device, and may be stored by being automatically input. Also, through experiments or the like, it is determined in advance according to the printing conditions such as the quality (type) of the printing medium (for example, printing paper), the force applied to the printing medium during printing, or the amount of water used. It may be stored for each printing condition. In this case, in printing, a printing condition suitable for the printing may be selected, and a correction value corresponding to the selected printing condition may be read. Furthermore, in the printing plate creation data generation method and apparatus of the present invention, printing conditions (for example, paper type, thickness, size, ink type to be used, ink amount, water amount, etc.) are detected. A printing condition detection step and means; and in the storage step and means, a relationship between the correction value and the printing condition is registered in advance, and the correction step and means are detected by the printing condition detection step and means. The correction value corresponding to the printing condition stored in the storing step and means may be automatically selected from the printed printing condition, and the expansion / contraction correction may be performed based on the selected correction value.

  As described above, according to the present invention, when performing CTP printing, it is not necessary to control the position correction of the imaging apparatus in the printing plate making apparatus, and therefore it is not necessary to provide a correction apparatus for each imaging apparatus. The cost can be reduced, and the image position at the time of creating the printing plate of the data for creating the printing plate that has been binarized (for example, network development) is not corrected. A decrease in print quality due to position correction can be prevented, and a phenomenon that the print medium gradually extends (extends in a trapezoidal shape) in a direction crossing the conveyance direction from the most downstream side to the most upstream side in the conveyance direction, so-called fan. Regardless of the occurrence of out, printing plate creation data generation that can accurately align the position of the pre-printed print image and the post-printed print image It is possible to provide a method and printing plate making data generating apparatus and the printing plate creation data generation program and a computer-readable recording medium recording the printing plate creation data generation program.

  Embodiments according to the present invention will be described below with reference to the drawings. FIG. 1 is a schematic configuration diagram of a CTP printing system 100 provided with an example 20 of a printing plate creation data generation apparatus that implements a printing plate creation data generation method according to the present invention.

  A CTP printing system 100 shown in FIG. 1 includes a printing data creation device 10, the printing plate creation data generation device 20, and a DI printer 50. The printing data creation device 10 generates printing plate creation data. It is connected to the DI printer 50 via the apparatus 20 via the network. In this CTP printing system 100, a plurality of printing plates respectively corresponding to a plurality of print images in the DI printer 50, in this example, cyan (C), magenta (M), yellow (Y), and black colors. Four printing plates corresponding to four different basic color printing images (K) are created, and the four printing images are printed on the printing medium (for example, printing paper Q) using the created printing plates. Are printed sequentially.

  In this example, the print data creation device 10 is a computer equipped with layout editing software and the like, and is print data corresponding to the four types of print images, and is based on PostScript (registered trademark) of Adobe Systems. The printing data PD can be created.

  The printing plate creation data generation device 20 includes a computer equipped with a printing plate creation data generation program P (in this example, software RIP), and print data PD transmitted from the device 10 is printed in a plurality of printing manners. Plate creation data, in this example, binarization data ADc for cyan printing plate creation, binarization data ADm for magenta printing plate creation, binarization data ADy for yellow printing plate creation, binarization for black printing plate creation The server RIP is configured to perform RIP development on the four printing plate creation data of the data ADk and generate the RIP-developed printing plate creation data ADc, ADm, ADy, ADk.

  The DI printing machine 50 is an on-press type printing machine capable of creating a plate in the machine, and includes printing plate creating apparatuses 40y, 40m, 40c, and 40k. The printing plate creating apparatuses 40y, 40m, 40c, and 40k are based on the four RIP-developed printing plate creating data ADc, ADm, ADy, and ADk transmitted from the RIP 20, respectively, and the cyan printing plate Ac and magenta. Four printing plates can be created: a printing plate Am, a yellow printing plate Ay, and a black printing plate Ak. The printing plates Ac, Am, Ay, Ak are created by the printing plate creating apparatuses 40y, 40m, 40c, 40k. For example, the printing images are formed on the unprepared printing plates provided in the apparatuses 40y, 40m, 40c, 40k, respectively. The imaging apparatus 41 that forms an image corresponding to the above-mentioned image is used to apply a laser beam in a predetermined sub-scanning direction and the sub-scanning direction to the unprepared printing plate based on the printing plate creation data ADc, ADm, ADy, ADk. This is done by scanning in the transverse main scanning direction.

  In the CTP printing system 100 described above, the print data creation apparatus 10 creates print data PD corresponding to a print image, and the RIP 20 prints the RIP 20 based on the created print data PD. Plate generation data ADc, ADm, ADy, ADk are generated, respectively, and based on the generated printing plate generation data ADc, ADm, ADy, ADk, printing plate generation apparatuses 40c, 40m, 40y, 40k are generated. Printing plates Ac, Am, Ay, Ak are created by the DI printing machine 50 provided, and printing is sequentially performed on the printing medium (for example, printing paper Q) by the created printing plates Ac, Am, Ay, Ak. . In the DI printing machine 50 of this example, as shown in FIG. 8, when the printing paper Q is transported in a predetermined transporting direction (first direction X), the printing paper Q when each printing is performed. The printing paper Q gradually extends (extends in a trapezoidal shape) in the direction (second direction Y) across the conveyance direction (first direction X) from the most downstream side to the most upstream side in the conveyance direction (first direction X). In this case, the expansion / contraction form of the printing paper Q is specified.

  As described above, the RIP 20 provided in the CTP printing system 100 generates the printing plate creation data ADc, ADm, ADy, ADk. The RIP 20 will be described in more detail with reference to FIG.

  FIG. 2 shows a schematic block diagram of the RIP 20 shown in FIG. As shown in FIG. 2, the RIP 20 includes a central processing unit 1, a main memory 2, a file device 3, an input device 4, an input port 5, and an output port 6, and print data generation connected to the input port 5. Based on the printing data PD sent from the apparatus 10, printing plate creation data ADc, ADm, ADy, ADk are generated, and the generated printing plate creation data ADc, ADm, ADy, ADk are output ports. 6 to the DI printer 50.

  The input device 4 includes a reading unit 4a that can read program information from a computer-readable recording medium 7 on which the printing plate creation data generation program P is recorded, and an input unit 4b such as a mouse or a keyboard. ing. The file device 3 can record the program information read from the recording medium 7 and stores in advance a correction value (or a relationship between the correction value and the printing condition), which will be described later, that can be used for the program P. I can keep it. The main memory 2 can read program information recorded in the file device 3 and has a program work area. Further, the central processing unit 1 can generate the printing plate creation data ADc, ADm, ADy, ADk based on the printing plate creation data generation program P read into the main memory 2.

  As shown in FIG. 1, the printing plate creating data generation program P includes a computer for printing condition detection means P0, storage means P1, conversion means P2, correction means P3, and binarization processing means P4. To function as a means including

  The printing condition detection means P0 detects printing conditions (for example, paper type, thickness, size, ink type to be used, ink amount, water amount, etc.). Various known means can be applied to the detection means, and the description thereof is omitted here. The conversion means P2 converts the printing data PD corresponding to the print image from the printing data creation device 10 into multivalued bitmap data for creating printing plate creation data. More specifically, the printing data PD corresponding to the printing image from the printing data creation device 10 is analyzed (interpreted) by the interpreter, and the printing plate creation data corresponding to the output device is rendered by rendering or painting. (In this example, raster data that has been bitmap-expanded) is converted into multi-valued bitmap data for creating. More specifically, as shown in FIG. 3, the print data PD corresponding to the print image from the print data creation device 10 is respectively corresponding to the second direction Y (see FIG. 8) of the print paper Q. A line of pixels arranged in parallel along the 2 ′ direction (Y ′ direction in FIG. 3) of m pixels (m is an integer of 2 or more) corresponds to the first direction X (see FIG. 8) of the printing paper Q. Pixel data D (i, j) (i = i) arranged in a line L ′ (j) (j = 1 to n) n (n is an integer of 2 or more) along the 1 ′ direction (X ′ direction in FIG. 3) 1 to m, j = 1 to n) is converted into multi-value data ADc ′, ADm ′, ADy ′, and ADk ′ for creating a printing plate.

  The storage means P1 stores in advance correction values for the amount of expansion / contraction in the direction to be expanded / contracted in the printing paper Q when each printing is performed, for each printing of the printing image on the printing paper Q by the printing plate. More specifically, the correction value for the amount of expansion / contraction to be expanded / contracted in a predetermined second direction Y across the first direction X with respect to a plurality of positions along the first direction X on the printing paper Q when each printing is performed is the file. Pre-stored in the device 3. More specifically, the relationship between the correction value and the printing condition is registered in advance. In this example, as shown in FIGS. 4A to 4D, as described above, the cyan image printing, the magenta image printing, the yellow image printing, and the black image printing are performed when the printing is performed. Since the expansion / contraction form of the printing paper Q is specified, the correction values stored in advance in the file device 3 are a plurality of positions along the first direction X on the printing paper Q when each printing is performed. There are a smaller number of lines than the plurality of lines L ′ (1) to L ′ (n) of the printing plate creation data ADc ′, ADm ′, ADy ′, ADk ′ shown in FIG. 3 (in this example, FIG. The first positions in the two positions L (1) and L (n) corresponding to the first downstream direction L ′ (1) and the most upstream line L ′ (n)). Correction values Hc (1) and Hc (for the expansion / contraction amount to be expanded / contracted in the two directions Y ), Is Hm (1) and Hm (n), Hy (1) and Hy (n), Hk (1) and Hk (n).

  In this example, the correction value stored in advance in the file device 3 in the storage unit P1 is the normal (in other words, before printing) size of the expansion / contraction amount in the second direction Y of the printing paper Q. Divided value (ie, expansion / contraction rate).

  In the correction means P3, each of the printing plate making multi-value data ADc ′, ADm ′, ADy ′, ADk ′ converted by the conversion means P2 is stored in the correction value stored in advance in the storage means P1. Based on this, the expansion / contraction correction in the direction corresponding to the direction to be expanded / contracted is performed. Furthermore, the correction value corresponding to the printing condition stored in the storage unit P1 is automatically selected from the printing conditions detected by the printing condition detection unit P0, and each selected line L ′ is selected. Based on the correction values corresponding to (1) to L ′ (n), expansion / contraction correction in the second ′ direction Y ′ in the line is performed. More specifically, in this example, the printing paper Q gradually extends (extends in a trapezoidal shape) in the second direction Y. First, the two positions L (1), L of the printing paper Q stored in advance are stored. The expansion / contraction ratios Hc (1) and Hc (n), Hm (1) and Hm (n), Hy (1) and Hy (n), and Hk (1) and Hk (n) in (n) 1) to expansion / contraction ratios Hc (jj), Hm (jj), Hy (jj), Hk (jj) (jj = 2 to n−1) corresponding to each line L ′ (jj) using the formula (4). Ask for.

Hc (jj) = Hc (1) + jj × [Hc (n) −Hc (1)] / (n−1) (1)
Hm (jj) = Hm (1) + jj × [Hm (n) −Hm (1)] / (n−1) Equation (2)
Hy (jj) = Hy (1) + jj × [Hy (n) −Hy (1)] / (n−1) Equation (3)
Hk (jj) = Hk (1) + jj × [Hk (n) −Hk (1)] / (n−1) Equation (4)
Here, n is an integer of 2 or more as described above.

  Next, when the expansion / contraction ratios H (1) to H (n) corresponding to the respective lines L ′ (1) to L ′ (n) are elongation ratios, the second ′ direction Y in the lines from the elongation ratios. The number of pixels Ec (j), Em (j), Ey (j), Ek (j) (j = 1 to n) to be increased along 'is calculated using the following equations (5) to (8). A process of calculating and inserting the increased pixels equally or substantially uniformly in the line is performed. In the formula, “||” indicates an absolute value symbol.

Ec (j) = m × | Hc (j) −1 | (5)
Em (j) = m × | Hm (j) −1 | (6)
Ey (j) = m × | Hy (j) −1 | (7)
Ek (j) = m × | Hk (j) −1 | (8)
Here, m is an integer of 2 or more as described above.

  At this time, for each of the lines L ′ (1) to L ′ (n), the value of the pixel data to be inserted is determined based on the value of the neighboring pixel data adjacent to the insertion position in the second ′ direction Y ′. To do. More specifically, as shown in FIG. 5, the value Da of the pixel data to be inserted is calculated from the value Db of one pixel data adjacent to the insertion position in the second ′ direction Y ′. One of the values Dc, in this example, the average value (Db + Dc) / 2 of the value Db of the one pixel data and the value Dc of the other pixel data is used.

  On the other hand, when the expansion / contraction ratios H (1) to H (n) corresponding to the respective lines L ′ (1) to L ′ (n) are contraction ratios, the second ′ direction in the lines from the contraction ratios. The number of pixels Ec (j), Em (j), Ey (j), Ek (j) (j = 1 to n) to be reduced along Y ′ is calculated using the above formulas (5) to (8). And a process of thinning out the reduced pixels equally or substantially equally in the line.

  In the binarization processing means P4, halftone processing is performed on the multivalue data ADc ′, ADm ′, ADy ′, and ADk ′ for printing plate creation that has been subjected to expansion / contraction correction by the correction means P3, and binary data for printing plate creation is obtained. Generated data ADc, ADm, ADy, ADk. Note that this halftoning process is a conventionally known process and will not be described in detail here.

  For the printing plate creation data ADc, ADm, ADy, ADk generated by the RIP 20, the first 'direction X' is the laser beam of the imaging device 41 in the printing plate creation devices 40y, 40m, 40c, 40k. The sub-scanning direction of scanning is the second 'direction Y', which is the main scanning direction of laser beam scanning of the imaging device 41.

  FIG. 6 is a flowchart showing the flow of processing by the printing plate creation data generation program P. In this program P, the printing conditions are detected by the printing condition detection means P0 (step S0), and the printing data PD from the printing data creation apparatus 10 is converted into the data by the conversion means P2 as shown in FIG. Pixel data D (i, j) (i = 1) in which n lines L ′ (j) are arranged along the first ′ direction X ′ in the line of m pixels arranged along the second ′ direction Y ′. To m, j = 1 to n) (see also FIG. 3), converted into multi-value data ADc ′, ADm ′, ADy ′, ADk ′ for creating a printing plate (step S1), and the converted printing plate is created The multivalued data ADc ′, ADm ′, ADy ′, and ADk ′ are subjected to expansion / contraction correction by the correction means P3 (steps S2 to S9).

  That is, first, the correction value corresponding to the printing condition stored in advance in the storage unit P1 is automatically selected from the printing condition detected in the printing condition detection unit P0, and the selected printing paper Q is selected. Expansion and contraction ratios Hc (1) and Hc (n), Hm (1) and Hm (n), Hy (1) and Hy (n), Hk (1) with respect to the two positions L (1) and L (n). ) And Hk (n) are read (step S2), and the expansion / contraction ratios correspond to the respective lines L ′ (jj) (jj = 2 to n−1) using the above formulas (1) to (4). The expansion / contraction ratios Hc (jj), Hm (jj), Hy (jj), and Hk (jj) are obtained (step S3).

  Next, when the expansion / contraction rates Hc (j), Hm (j), Hy (j), and Hk (j) corresponding to each line L ′ (j) are elongation rates (step S4), In the line, the number of pixels Ec (j), Em (j), Ey (j), Ek (j) to be increased along the second 'direction Y' is calculated using the above equations (5) to (8). (Step S5), and the pixels to be increased are inserted equally or substantially equally in the line (step S6). At this time, as shown in FIG. 5, as the value Da of the pixel data to be inserted, one pixel data value Db and the other pixel data value Dc that are adjacent to each other at the insertion position in the second 'direction Y'. (Db + Dc) / 2 is obtained (step S7).

  When the expansion / contraction ratios Hc (j), Hm (j), Hy (j), and Hk (j) corresponding to each line L ′ (j) are contraction ratios (step S4), the contraction ratios are The number of pixels Ec (j), Em (j), Ey (j), Ek (j) to be reduced along the second 'direction Y' in the line is calculated using the above equations (5) to (8). The calculation is performed (step S8), and the pixels to be reduced are thinned out equally or substantially uniformly in the line (step S9).

  Then, the multivalue data ADc ′, ADm ′, ADy ′, and ADk ′ for printing plate creation subjected to the expansion / contraction correction in steps S2 to S9 are subjected to halftone dot processing by the binarization processing means P4 (step S10).

  As described above, in the printing plate creation data generation device 20 and the printing plate creation data generation program P, the printing plates Ac, Am, and printing plates created by the printing plate creation devices 40c, 40m, 40y, and 40k included in the DI printer 50 are used. Prior to the creation of Ay and Ak, the expansion / contraction correction of the multi-value data for printing plate creation is performed, so that it is not necessary to control the position correction of the imaging device 41 in the printing plate creation devices 40c to 40k. Therefore, it is not necessary to provide a correction device for each imaging device 41, and the device cost can be reduced accordingly. Further, prior to the binarization processing of the printing plate creation multi-value data ADc ′ to ADk ′, the expansion / contraction correction of the printing plate creation multi-value data ADc ′ to ADk ′ is performed, so that the binarized printing plate creation is performed. It is not necessary to correct the image position when creating the printing plates Ac to Ak of the data for use ADc to ADk. Therefore, it is possible to prevent a decrease in print quality due to image position correction at the time of creating a printing plate. On the other hand, what is corrected with the binarized data changes the halftone dot shape compared to the original.

  Further, in the correction means P3, for each of the printing plate making multi-value data ADc ′ to ADk ′ converted by the conversion means P2, based on the correction values stored in advance in the storage means P1, Since the expansion / contraction correction in the direction corresponding to the direction to be expanded / contracted is performed, in this example, the correction value stored in advance in the storage unit P1 corresponding to each line L ′ (1) to L ′ (n) is used. Based on this, the expansion and contraction correction in the second 'direction Y' in the line is performed. For example, a phenomenon in which the printing paper Q gradually extends in the direction Y crossing the conveyance direction X from the most downstream side to the most downstream side in the conveyance direction X, so-called fan. Even if out occurs, correction is performed to extend in the direction Y across the conveyance direction X from the most downstream side to the most upstream side in the conveyance direction X of the printing paper Q, so the accuracy of the pre-printed print image and the post-printed print image is improved. Well Can be put together.

  Therefore, according to the printing plate creation data generation device 20 and the printing plate creation data generation program P, when performing CTP printing, the position correction of the imaging device 41 in the printing plate creation devices 40c to 40k is not performed. In addition, it is not necessary to provide a correction device for each imaging device 41, the device cost can be reduced by that much, and when the printing plates Ac to Ak of the binarized printing plate creation data ADc to ADk are created. Therefore, it is possible to prevent deterioration in print quality due to image position correction at the time of preparing a printing plate, and further, in the transport direction X of the printing paper Q from the most downstream side to the most upstream side. Regardless of the occurrence of the so-called fan-out phenomenon, which gradually extends in the direction Y across the conveying direction X (extends in a trapezoidal shape). A print image of Rino print image and the rear printed can be combined accurately position.

  Further, in this example, when the correction values corresponding to the lines L ′ (1) to L ′ (n) are correction values for the expansion amount, the pixels to be increased with respect to the expansion amount are equally or substantially equal in the line. When the correction value is a correction value for the shrinkage amount, pixels to be reduced with respect to the shrinkage amount are thinned out evenly or substantially equally in the line, so that the expansion correction is performed while substantially maintaining the original print image. It can be carried out.

  Further, in this example, the correction values stored in advance are a plurality of positions along the first direction X on the printing paper Q when each printing is performed, and the printing plate creation data ADc ′ to ADk ′. With respect to the amount of expansion / contraction to be expanded / contracted in the second direction Y with respect to the two positions corresponding to the two lines of the line L ′ (1) on the most downstream side in the first ′ direction X ′ and the line L ′ (n) on the most upstream side Since it is a correction value, the storage capacity of the file device 3 can be reduced.

  In the CTP printing system 100 of this example, the DI printing machine 50 including the printing plate creating apparatuses 40c, 4om, 40y, and 40k is used. Of course, a printing plate creating apparatus arranged separately from the printing machine is used. The printing plates Ac to Ak are sequentially created based on the printing plate creation data ADc to ADk, and the created printing plates Ac to Ak are provided in the printing machine to perform printing on the printing paper Q. Similar effects can be achieved.

  Further, in this example, expansion / contraction correction in the main scanning direction Y ′ of the laser beam scanning is performed on the printing plate preparation data, but expansion / contraction correction in the sub-scanning direction X ′ of the laser beam scanning may be performed. In this example, expansion / contraction correction is performed on the printing plate creation data ADc ′ to ADk ′ for cyan, magenta, yellow, and black, but at least one of them may be subjected to expansion / contraction correction. When the body Q is not initially formed with an image, or when the image is initially formed, the image need not be aligned with the position of the image to be printed. The expansion / contraction correction may be omitted for the printing plate creation data ADc ′ for the first printing. In this case, the expansion / contraction amount may be a value (that is, expansion / contraction rate) divided by the dimension after the first printing in the second direction Y of the printing paper Q (in other words, before the second printing).

1 is a schematic configuration diagram of a CTP printing system including an example of a printing plate creation data generation apparatus that performs a printing plate creation data generation method according to the present invention. It is a schematic block diagram of an example (RIP) of the data generation apparatus for printing plate creation shown in FIG. It is a figure which shows the state by which the multivalue data for printing plate preparation were bitmap-expanded. FIGS. (A) to (D) are correction values stored in advance in the file device. The correction values at the time of cyan image printing, magenta image printing, yellow image printing, and black image printing will be described. FIG. It is a figure which shows the state by which one pixel is inserted about each line. It is a flowchart which shows the flow of the process by the data generation program P for printing plate preparation. It is a figure which shows schematic structure of the conventional CTP printing, creates a printing plate using a printing plate creation apparatus based on the printing plate creation data in FIGS. (A) and (C), and the created printing A configuration is shown in which a printing plate is printed on a printing medium, and a printing plate is created using a DI printing machine equipped with a printing plate creation device based on the printing plate creation data shown in Fig. (B). In addition, a configuration is shown in which printing is performed on a printing medium using the created printing plate. It is a figure for demonstrating an example of the state of elongation in the to-be-printed body (for example, printing paper) printed with the printing machine using a some printing plate.

Explanation of symbols

DESCRIPTION OF SYMBOLS 20 ... Data generation apparatus for printing plate creation 50 ... Printing machine (DI printing machine) 7 ... Recording medium ADc, ADm, ADy, ADk ... Printing plate creation data Ac, Am, Ay, Ak ... Printing plate P ... Printing plate creation Data generation program P1 ... Storage means P2 ... Conversion means P3 ... Correction means PD ... Print data Q ... Print paper X ... First direction X '... First' direction Y ... Second direction Y '... Second' direction

Claims (4)

A method of generating printing plate creation data for creating a plurality of printing plates when sequentially printing the plurality of printing images on a printing medium using a plurality of printing plates respectively corresponding to the plurality of printing images. There,
For each printing of the plurality of print images on the printing medium by the plurality of printing plates, a correction value for the amount of expansion / contraction in the direction to be stretched in the printing medium when each printing is performed is stored in advance. A storage step,
A conversion step of converting print data corresponding to the plurality of print images into multi-value data for creating a printing plate;
The printing plate making multi-value data converted in the conversion step is subjected to expansion / contraction correction in a direction corresponding to the direction to be expanded / contracted based on the correction value stored in advance in the storage step. A correction step;
A binarization processing step for converting the printing plate creation multi-value data subjected to expansion / contraction correction in the correction step into halftone dot printing plate creation binary data ,
In the storing step, for each printing of the plurality of print images on the printing medium by the plurality of printing plates, a plurality of positions along a predetermined first direction on the printing medium when each printing is performed A correction value for the amount of expansion / contraction to be expanded / contracted in a predetermined second direction crossing the first direction with respect to
In the conversion step, for print data corresponding to the plurality of print images, a line of pixels arranged in parallel along a second ′ direction corresponding to the second direction corresponds to the first direction. Converting into multi-value data for creating a printing plate consisting of pixel data arranged in a plurality of lines along the first 'direction,
In the correction step, for the printing plate making multi-value data converted in the conversion step, based on the correction value stored in advance in the storage step corresponding to each line, the line in the line A data generation method for creating a printing plate, comprising performing second-direction expansion / contraction correction . An apparatus that generates printing plate creation data for creating a plurality of printing plates when sequentially printing the plurality of printing images on a printing medium using a plurality of printing plates respectively corresponding to the plurality of printing images. There,
For each printing of the plurality of print images on the printing medium by the plurality of printing plates, a correction value for the amount of expansion / contraction in the direction to be stretched in the printing medium when each printing is performed is stored in advance. Storage means,
Conversion means for converting print data corresponding to the plurality of print images into multi-value data for creating a printing plate;
The multi-value data for creating a printing plate converted by the conversion unit is subjected to expansion / contraction correction in a direction corresponding to the direction to be expanded / contracted based on the correction value stored in advance in the storage unit. Correction means;
Binarization processing means for converting the printing plate creation multi-value data subjected to expansion and contraction correction by the correction means into halftone dot printing plate creation binary data ;
In the storage unit, a plurality of positions along a predetermined first direction in the printing medium when each printing is performed with respect to each printing of the plurality of print images on the printing medium by the plurality of printing plates. A correction value for the amount of expansion / contraction to be expanded / contracted in a predetermined second direction crossing the first direction with respect to
In the conversion means, for printing data corresponding to the plurality of print images, a line of pixels arranged in parallel along a second 'direction corresponding to the second direction corresponds to the first direction. Converting into multi-value data for creating a printing plate consisting of pixel data arranged in a plurality of lines along the first 'direction,
In the correction means, for the printing plate making multi-value data converted by the conversion means, based on the correction value stored in advance in the storage means corresponding to each line, the line in the line A data generation apparatus for creating a printing plate, characterized by performing expansion and contraction correction in the second direction . A printing plate creation data generation program for causing a computer to execute each step of the printing plate creation data generation method according to claim 1 . A computer-readable recording medium on which the printing plate creating data generating program according to claim 3 is recorded.