JP5685944B2 - Image processing apparatus and image forming apparatus - Google Patents

Description

  The present invention relates to an image processing apparatus and an image forming apparatus.

  2. Description of the Related Art Conventionally, a technique is known in which printing is performed by adding other colors to the four colors of CMYK used in normal printing in order to improve the quality of printed matter. For example, Patent Document 1 discloses a color printing system that performs printing using five colors including CMYK.

  However, in the technique disclosed in Patent Document 1, it is necessary to individually design screen angles and the like for all colors assumed as additional colors other than CMYK. In other words, dither data must be individually designed and prepared for all colors that are assumed as additional colors other than CMYK. Therefore, it is necessary for the design process for gradation processing and the memory that holds the dither data. There is a problem that the capacity increases.

  The present invention has been made in view of the above, and it is an object of the present invention to provide an image processing apparatus and an image forming apparatus capable of reducing the design man-hour for gradation processing and the capacity required for a memory for holding dither data. Objective.

In order to solve the above-described problems and achieve the object, an image processing apparatus of the present invention includes a dither processing unit that performs dither processing of multi-tone input image data using dither data, and the dither data is , C, M, Y, K plates are used for the dither processing of the input image data, and the screen angles of the C, M, Y, K plate image data after the dither processing are set to be different from each other. Are used for the dither processing of the four line dither data and the input image data of the R, G, B versions, and the screen angle of each of the R, G, B plane image data after the dither processing is C , M, Y, and K, three line dither data set to be the same as the screen angle of the complementary color, and color plates other than C, M, Y, K, R, G, and B In the dither processing of the input image data The screen angle of the color image data other than C, M, Y, K, R, G, B after the dither processing is used is a screen of any two colors of C, M, Y, K two ten thousand linear dither data is set so that the angle between the angle, only contains the two ten thousand linear dither data, the 1 C, M, Y, K , R, G, other than B First line dither data for the second color, and second line dither data for the second color other than C, M, Y, K, R, G, B. In the linear dither data, the screen angle of the image data after the dither processing using the first multi-line dither data does not overlap with the screen angles of C, M, Y, and K. Between two screen angles that correspond to any two colors of Y and K and are adjacent to each other The second line dither data is set to be an angle, and the screen angle of the image data after the dither processing using the second line dither data is C, M, Y, K, respectively. The angle between two screen angles corresponding to two colors different from any two of C, M, Y, and K and adjacent to each other is not overlapped with the screen angle. It is set as follows. According to another aspect of the present invention, there is provided an image forming apparatus including an image forming unit that forms an image on a medium based on image data image-processed by the image processing apparatus.

  According to the present invention, each of the three line dither data used for dither processing of R, G, B version input image data has a screen angle of the image data after dither processing using the line dither data. , C, M, Y, K are set to be the same as the screen angle of the complementary color, and the dither of the input image data of the color plate other than C, M, Y, K, R, G, B Since only two lines of dither data are used for the processing, there are advantageous effects that the design man-hours for the gradation processing and the capacity required for the memory holding the dither data can be reduced.

FIG. 1 is a block diagram illustrating an example of a schematic configuration of an image input / output system according to an embodiment. FIG. 2 is a diagram illustrating an example of the structure of the image forming unit. FIG. 3 is a block diagram illustrating an example of a schematic configuration of the image processing apparatus. FIG. 4 is a block diagram illustrating an example of a detailed configuration of the first halftone processing unit. FIG. 5 is a diagram for explaining line dither data for the CMYK version. FIG. 6 is a block diagram illustrating an example of a detailed configuration of the second halftone processing unit. FIG. 7 is a view for explaining line dither data for the RGB version. FIG. 8 is a diagram for explaining other line dither data for additional colors. FIG. 9 is a diagram for explaining a modified example of the line dither data for other additional colors. FIG. 10 is a diagram for explaining a modified example of the line dither data for the CMYK version.

<Embodiment>
Hereinafter, an embodiment of an image processing apparatus and an image forming apparatus according to the present invention will be described in detail with reference to the accompanying drawings. FIG. 1 is a block diagram illustrating an example of a schematic configuration of an image input / output system according to the present embodiment. The image input / output system includes an image input device 301, an image processing device 302, and an image forming device 303.

  The image input device 301 is an input device such as a scanner or a digital camera. In the image input device 301, for example, if the input image has an 8-bit precision, it is captured as 256-gradation image data. The multivalued image data captured by the image input device 301 is input to the image processing device 302.

  The image processing apparatus 302 performs a process of converting (quantizing) the multi-value image data input from the image input apparatus 301 into the number of gradations that can be output by the image forming apparatus 303 in the subsequent stage. Dither processing is used for the tone number conversion processing. When the number of gradations that can be output by the image forming apparatus 303 is binary, dither processing is performed so that the input multi-value image data is binarized, and in the case of 4-value, the input multi-value Dither processing is performed so that the image data is binarized. Here, it is assumed that the number of gradations that can be output by the image forming apparatus 303 is binary. The image data quantized by the image processing apparatus 302 is sent to the image forming apparatus 303.

  The image forming apparatus 303 includes an image forming unit 310 (described later) that forms an image on a medium such as paper based on the image data subjected to image processing (dither processing or the like) by the image processing apparatus 302. As will be described in detail later, the image forming apparatus 303 according to the present embodiment has two additional colors (hereinafter, for convenience of explanation) in addition to basic colors of C (cyan), M (magenta), Y (yellow), and K (black). 6 plate printing including A and B) is possible. Additional colors of the present embodiment include R (red), G (green), B (blue), Lc (light cyan), Lm (light magenta), Dg (dark gray), Lg (light gray), transparent, blue gold , Silver, red gold, etc.

  FIG. 2 is a diagram illustrating an example of the structure of the image forming unit 310. In the present embodiment, the image forming unit 310 forms an image by an electrophotographic method, but the image forming unit 310 is not limited thereto, and can also form an image by, for example, an ink jet method. As shown in FIG. 2, the image forming unit 310 forms toner images of Y, M, C, K, A, and B on the peripheral surfaces of a plurality of image forming members, and these are formed on the intermediate transfer member. After superimposing and transferring (primary transfer), the transfer material is retransferred (secondary transfer).

  The image forming units 50B, 50A, 50Y, 50M, 50C, and 50K for B, A, Y, M, C, and K are provided on the transfer belt 14 that is a belt-shaped intermediate transfer member, on the upstream side in the rotation direction of the transfer belt 14. Are arranged in order. Each of the image forming units 50 </ b> B, 50 </ b> A, 50 </ b> Y, 50 </ b> M, 50 </ b> C, and 50 </ b> K includes a photosensitive drum 10, a charger 11, an exposure optical system 12, a developing device 13, and a cleaning device 20. The B, A, Y, M, C, and K toner images formed in each image forming unit 50 are sequentially superimposed on the surface of the transfer belt 14 and transferred (primary transfer). As a result, a color toner image is formed on the surface of the transfer belt 14.

  The above-described color toner images are transferred collectively (secondary) to the surface of the recording paper P fed from the paper feed cassette 15 via the timing roller 16 by a discharge action having a polarity opposite to that of the toner of the transfer unit 17. Transferred). Then, after the toner is welded in the fixing device 18, the toner turns in the horizontal direction and is discharged to the tray 19 at the top of the device. After the transfer, the transfer belt 14 has the residual toner removed by the cleaning device 20.

  FIG. 3 is a block diagram illustrating an example of a schematic configuration of the image processing apparatus 302. As shown in FIG. 3, the image processing apparatus 302 includes input terminals 101 and 106, a screen selection unit 102, a first halftone processing unit 103, a second halftone processing unit 104, a synthesis unit 105, and an output. Terminal 107.

  Multi-value image data from the image input device 301 is input to the input terminal 101. Here, the input multi-value image data is two-dimensional image data and is represented as In (x, y). x indicates an address in the main scanning direction of the image, while y indicates an address in the sub scanning direction of the image. This multi-valued image data In (x, y) is CMYK + AB composite data. The multivalued image data In (x, y) input to the input terminal 101 is supplied to the screen selection unit 102.

  On the other hand, information S (described later) of additional colors A and B is input to the input terminal 106 from an operator unit (not shown). The information S input to the input terminal 106 is supplied to the second halftone processing unit 104.

  The screen selection unit 102 converts the multivalued image data In (x, y) supplied from the input terminal 101 into CMYK version composite data CMYK (x, y) and AB version composite data AB (x, y). Disassembled into Then, the screen selection unit 102 supplies the CMYK version composite data CMYK (x, y) to the first halftone processing unit 103 and the AB version composite data AB (x, y) to the second halftone processing unit 104. To supply.

  The first halftone processing unit 103 binarizes the CMYK plane composite data CMYK (x, y) supplied from the screen selection unit 102 by a method described later. The binarized CMYK composite data CMYK_out (x, y) is supplied to the combining unit 105.

  The second halftone processing unit 104 uses the AB version composite data AB (x, y) supplied from the screen selection unit 102 and the information S supplied from the input terminal 106 to perform binary processing according to a method described later. Turn into. The binarized AB version combined data AB_out (x, y) is supplied to the combining unit 105.

  The synthesizing unit 105 includes the binarized CMYK version synthesized data CMYK_out (x, y) supplied from the first halftone processing unit 103 and the binarized post-binary data supplied from the second halftone processing unit 104. The synthesized data AB_out (x, y) of the AB version is synthesized. The combined data Out (x, y) is supplied to the output terminal 107. The output terminal 107 outputs composite data Out (x, y) to the image forming apparatus 303 (see FIG. 1).

  FIG. 4 is a block diagram illustrating an example of a detailed configuration of the first halftone processing unit 103. As shown in FIG. 4, the first halftone processing unit 103 includes an input terminal 401, a CMYK decomposition unit 402, a C version γ conversion unit 403, an M version γ conversion unit 405, and a Y version γ conversion unit 407. , K plate γ conversion unit 409, C plate dither processing unit 404, M plate dither processing unit 406, Y plate dither processing unit 408, K plate dither processing unit 410, CMYK synthesis unit 411, and output terminal 412. And having.

  The input terminal 401 is supplied with CMYK version composite data CMYK (x, y) from the screen selection unit 102. The input terminal 401 supplies the CMYK version of the composite data CMYK (x, y) to the CMYK decomposition unit 402.

  The CMYK decomposition unit 402 converts CMYK version composite data CMYK (x, y) into C version data C (x, y), M version data M (x, y), Y version data Y (x, y), and K. The data is decomposed into plate data K (x, y). The C plate data C (x, y) is supplied to the subsequent C plate γ conversion unit 403, and the M plate data M (x, y) is supplied to the subsequent M plate γ conversion unit 405, and the Y plate data Y (X, y) is supplied to the subsequent Y version γ conversion unit 407, and the K version data K (x, y) is supplied to the subsequent K version γ conversion unit 409.

  The C plate γ conversion unit 403 performs γ conversion on the C plate data C (x, y), and supplies the C plate data gc (x, y) after γ conversion to the C plate dither processing unit 404 in the subsequent stage. The C plate dither processing unit 404 reads C plate dither data (matrix data) from a memory (not shown), and uses the read C plate dither data to perform C plate data gc (x, y after γ conversion). ) Is dithered. Thereby, the C plane data gc (x, y) after γ conversion is binarized. Then, the C version data oc (x, y) after binarization (after dither processing) is supplied to the CMYK synthesis unit 411 at the subsequent stage. In this embodiment, the dither data for the C plate is set so that the resolution of the C plate image data after dither processing using the dither data is 600 dpi, the screen line number is 190 lpi, and the screen angle is 18 °. Line dither data (see FIG. 5).

  4 γ-converts the M plate data M (x, y), and supplies the M plate data gm (x, y) after γ conversion to the M plate dither processing unit 406 at the subsequent stage. To do. The M version dither processing unit 406 reads M version dither data from a memory (not shown), and uses the read M version dither data for the M version data gm (x, y) after γ conversion. Perform dithering. As a result, the M plate data gm (x, y) after γ conversion is binarized. Then, the binarized M plate data om (x, y) is supplied to the CMYK synthesis unit 411 at the subsequent stage. In the present embodiment, the dither data for the M plate is set so that the resolution of the M plate image data after dither processing using the dither data is 600 dpi, the screen line number is 190 lpi, and the screen angle is 108 °. Line dither data (see FIG. 5).

  4 γ-converts the Y plate data Y (x, y) and supplies the Y plate data gy (x, y) after γ conversion to the Y plate dither processing unit 408 at the subsequent stage. To do. The Y version dither processing unit 408 reads Y version dither data from a memory (not shown), and uses the read Y version dither data for the Y version data gy (x, y) after γ conversion. Perform dithering. Thereby, the Y plane data gy (x, y) after γ conversion is binarized. Then, the binarized Y plane data oy (x, y) is supplied to the CMYK synthesis unit 411 at the subsequent stage. In this embodiment, the dither data for the Y plate is set so that the resolution of the Y plate image data after dither processing using the dither data is 600 dpi, the screen line number is 190 lpi, and the screen angle is 162 °. Line dither data (see FIG. 5).

  4 performs γ conversion on the K plate data K (x, y), and supplies the K plate data gk (x, y) after γ conversion to the K plate dither processing unit 410 at the subsequent stage. To do. The K version dither processing unit 410 reads the K version dither data from a memory (not shown), and uses the read K version dither data for the K version data gk (x, y) after γ conversion. Perform dithering. Thereby, the K plate data gk (x, y) after γ conversion is binarized. The binarized K plate data ok (x, y) is supplied to the CMYK synthesis unit 411 at the subsequent stage. In this embodiment, the dither data for the K plate is set so that the resolution of the K plate image data after dither processing using the dither data is 600 dpi, the screen line number is 190 lpi, and the screen angle is 72 °. Line dither data (see FIG. 5).

  The CMYK synthesis unit 411 illustrated in FIG. 4 performs binarized C plate data oc (x, y), binarized M plate data om (x, y), and binarized Y plate data oy ( x, y) and binarized K version data ok (x, y) are synthesized to generate binarized CMYK version synthesized data CMYK_out (x, y). The combined data CMYK_out (x, y) generated by the CMYK combining unit 411 is supplied to the output terminal 412. The output terminal 412 outputs the binarized CMYK version of the combined data CMYK_out (x, y) to the combining unit 105 shown in FIG.

  FIG. 6 is a block diagram illustrating an example of a detailed configuration of the second halftone processing unit 104 illustrated in FIG. 3. As shown in FIG. 6, the second halftone processing unit 104 includes input terminals 501 and 507, an AB decomposition unit 502, an AB information decomposition unit 514, an A version γ conversion unit 503, and a B version γ conversion unit 505. A plate γ setting unit 510, B plate γ setting unit 508, A plate dither processing unit 504, B plate dither processing unit 506, A plate dither data setting unit 511, and B plate dither data setting unit 509. And an AB combining unit 512 and an output terminal 513.

  AB input composite data AB (x, y) is supplied from the screen selection unit 102 to the input terminal 501. The input terminal 501 supplies the AB version of the combined data AB (x, y) to the AB decomposition unit 502.

  The AB decomposition unit 502 decomposes the AB version composite data AB (x, y) into A version data A (x, y) and B version data B (x, y). The A plate data A (x, y) is supplied to the subsequent A plate γ conversion unit 503, and the B plate data B (x, y) is supplied to the subsequent B plate γ conversion unit 505.

  Information S of the additional colors A and B is supplied to the input terminal 507 from the input terminal 106 shown in FIG. The input terminal 507 supplies the information S to the AB information decomposing unit 514. In this embodiment, the information S is data obtained by combining data indicating the color information of the additional colors A and B, and the AB information decomposing unit 514 converts the information S supplied from the input terminal 106 into the additional color. The information is decomposed into A information sa (x, y) indicating the color information of A and B information sb (x, y) indicating the color information of the additional color B. As described above, the types of colors indicated by the A information sa (x, y) or the B information sb (x, y) are R, G, B, Lc, Lm, Dg, Lg, transparent, blue gold, There are silver and red gold. The A information sa (x, y) is supplied to the A version γ setting unit 510 and the A version dither data setting unit 511, respectively. Further, the B information sb (x, y) is supplied to each of the B version γ setting unit 508 and the B version dither data setting unit 509.

  The A version γ setting unit 510 holds γ tables of R, G, B, Lc, Lm, Dg, Lg, transparency, blue gold, silver, and red gold, which are assumed as additional colors. AB information decomposition The γ data gA is read from the γ table of the color indicated by the A information sa (x, y) supplied from the unit 514. Then, the A version γ setting unit 510 supplies the read γ data gA to the A version γ conversion unit 503. The A version γ conversion unit 503 uses the γ data gA supplied from the A version γ setting unit 510 to γ convert the A version data A (x, y) supplied from the AB decomposition unit 502. The A plate data ga (x, y) after γ conversion is supplied to the A plate dither processing unit 504 at the subsequent stage.

  Similarly, the B version γ setting unit 508 holds γ tables of R, G, B, Lc, Lm, Dg, Lg, transparency, blue gold, silver, and red gold assumed as additional colors. The γ data gB is read from the γ table of the color indicated by the B information sb (x, y) supplied from the AB information decomposing unit 514. Then, the B version γ setting unit 508 supplies the read γ data gB to the B version γ conversion unit 505. The B plate γ conversion unit 505 performs γ conversion on the B plate data B (x, y) supplied from the AB decomposition unit 502 using the γ data gB supplied from the B plate γ setting unit 508. The B plate data gb (x, y) after γ conversion is supplied to the B plate dither processing unit 506 at the subsequent stage.

  The A-size dither data setting unit 511 reads dither data corresponding to the color indicated by the A information sa (x, y) supplied from the AB information decomposing unit 514 from a memory (not shown), and reads the read dither data dA. This is supplied to the dither processing unit 504. In the memory (not shown), the dither data for the R plate, the dither data for the B plate, the dither data for the G plate, and the C, M, Two dither data for colors other than Y, K, R, G, and B are held. Hereinafter, specific contents of each dither data will be described.

  Here, due to complementary colors, R dots and C dots, G dots and M dots, and B dots and Y dots do not overlap each other. For example, the R dot is generated from an M dot and a Y dot, and the fact that the R dot and the C dot overlap is a condition that the C dot, the M dot, and the Y dot overlap. In this case, a K dot is generated. It becomes a condition. That is, the R dot and the C dot do not overlap. The same applies to G dots and M dots, and B dots and Y dots. Using this complementary color relationship, in this embodiment, each of the three dither data for the R, G, and B plates has a screen angle of the image data after dither processing using the dither data is C, M. , Y, K are set to be the same as the screen angle of the complementary color.

  More specifically, in the dither data for the R plate, the screen angle of the R plate image data after the dither processing using the dither data corresponds to the complementary color of R among C, M, Y, and K. The dither data for the G plate has a screen angle of the G plate image data after dithering using the dither data, and the screen angle of G, C, M, Y, and K is G. The B screen dither data is set to have the same screen angle as that of the B plate image data after dithering using the dither data. The Y screen angle is set to be the same as the Y screen angle corresponding to the B complementary color. More specifically, as shown in FIG. 7, the dither data for the R plate has a resolution of 600 dpi, a screen line number of 190 lpi, and a screen angle after binarization (after dithering). This is line-type dither data set so as to be 18 °. Further, the dither data for the G plate is line dither data set so that the resolution of the G plate image data after the dither processing is 600 dpi, the screen line number is 190 lpi, and the screen angle is 108 °. Further, the dither data for the B plate is line dither data set so that the resolution of the B plate image data after the dither processing is 600 dpi, the screen line number is 190 lpi, and the screen angle is 162 °.

  In this embodiment, each of the two dither data for colors other than C, M, Y, K, R, G, and B has the screen angle of the image data after the dither processing using the dither data, It is set to be an angle between any two of the basic colors C, M, Y, and K, and the number of screen lines of the dithered image data is C, M, Y , K, R, G, B are set to be higher. Here, as dither data for colors other than C, M, Y, K, R, G, and B, dither data for Lm, Lg, blue gold, and silver plate, and Lc, Dg, red gold, and transparent plate And dither data for use. As shown in FIG. 8, the dither data for Lm, Lg, blue gold, and silver plate has a resolution of 600 dpi, a screen line number of 212 lpi, and a screen angle after dither processing using the dither data. This is line-type dither data set to be 45 °. In other words, the line dither data for Lm, Lg, blue gold, and silver plate has the screen angle of the image data after the dither processing using the line dither data is C screen angle (18 °) and K It is set to be an angle between the screen angle (72 °). The dither data for Lc, Dg, red gold, and transparent plate is set so that the resolution of the image data after dither processing using the dither data is 600 dpi, the screen line number is 212 lpi, and the screen angle is 135 °. Line dither data. That is, the line dither data for Lc, Dg, red gold, and transparent plate has a screen angle of the image data after dithering using the line dither data is M screen angle (108 °) and Y screen. It is set to be an angle between the angle (162 °).

  In the present embodiment, the line dither data for Lm, Lg, blue gold, and silver plate, and the line dither data for Lc, Dg, red gold, and transparent plate are each dither using the line dither data. The screen angle of the image data after processing is an angle between the screen angles of two colors (here, C and K and M and Y) having the largest screen angle difference among C, M, Y, and K. Therefore, the occurrence of moire can be suppressed. In addition, since the angle difference between the screen angle (18 °) of the C plate and the screen angle (135 °) of the Lc plate is sufficiently secured, it is difficult for moire to occur even in similar colors with different brightness. Similarly, the angle difference between the screen angle (108 °) of the M plate and the screen angle (45 °) of the Lm plate is sufficiently ensured, so that it is difficult to cause moire even in similar colors with different brightness. . Furthermore, by increasing the number of screen lines of Lc, Lm used in the highlight portion, and transparent, blue gold, silver, and red gold for producing glossiness and metallic feeling as compared with the CMYK version, the texture becomes difficult to perceive.

  As described above, in the memory (not shown), in addition to the line dither data for the C, M, Y, and K versions, the line dither data for the R version, the line dither data for the B version, and the G version Line dither data for Lm, Lg, blue gold, and silver plates, and line dither data for Lc, Dg, red gold, and transparent plates are held. As described above, the A-size dither data setting unit 511 receives the line-type dither data dA corresponding to the color indicated by the A information sa (x, y) supplied from the AB information decomposing unit 514 from a memory (not shown). This is read and supplied to the A version dither processing unit 504. For example, when the A information sa (x, y) supplied from the AB information decomposing unit 514 indicates Lm, the A-size dither data setting unit 511 reads Lm, Lg, blue gold, That is, the line dither data for the silver plate is read out, and the read line dither data is supplied to the A plate dither processing unit 504.

  Similarly, the B version dither data setting unit 509 reads line dither data dB corresponding to the color indicated by the B information sb (x, y) supplied from the AB information decomposing unit 514 from a memory (not shown), and The data is supplied to the processing unit 506. For example, when the B information sb (x, y) supplied from the AB information decomposing unit 514 indicates Lc, the B version dither data setting unit 509 reads Lc, Dg, red gold, transparent from a memory (not shown). For example, the line dither data for the plate is read, and the read line dither data is supplied to the B plate dither processing unit 506.

  The A version dither processing unit 504 uses the line-type dither data dA supplied from the A version dither data setting unit 511 to the A version data ga (x, y) supplied from the A version γ conversion unit 503. Perform dithering. Thereby, the A version data ga (x, y) is binarized. The binarized A-plate data oa (x, y) is supplied to the subsequent AB combining unit 512. Similarly, the B plate dither processing unit 506 uses the line dither data dB supplied from the B plate dither data setting unit 509 to use the B plate data gb (x, y) supplied from the B plate γ conversion unit 505. Dither processing is performed on Thereby, the B plate data gb (x, y) is binarized. The binarized B board data ob (x, y) is supplied to the subsequent-stage AB combining unit 512.

  The AB combining unit 512 is a binarized A plate data oa (x, y) supplied from the A plate dither processing unit 504 and a binarized B plate data supplied from the B plate dither processing unit 506. OB (x, y) is synthesized to generate binarized AB version synthesized data AB_out (x, y). The combined data AB_out (x, y) generated by the AB combining unit 512 is supplied to the output terminal 513. The output terminal 513 outputs the binarized AB version of the combined data CMYK_out (x, y) to the combining unit 105 shown in FIG.

<Action and effect>
As described above, according to the present embodiment, each of the three line dither data used for dither processing of the input image data of the R, G, and B versions is dithered using the line dither data. The screen angle of the subsequent image data is set to be the same as the screen angle of the complementary color of C, M, Y, K, and other than C, M, Y, K, R, G, B Since only two line-type dither data is used for dither processing of the input image data of the color plate, there is an advantageous effect that the number of man-hours for gradation processing and the capacity required for the memory holding the dither data can be reduced. Play.

<Modification>
In the above embodiment, each of the two line dither data for color plates other than C, M, Y, K, R, G, and B is the image data after dither processing using the line dither data. The screen angle is set to 45 ° or 135 °, but not limited to this, each of the two line dither data for colors other than C, M, Y, K, R, G, B Is set so that the screen angle of the image data after the dither processing using the line dither data is an angle between any two of the basic colors C, M, Y, and K. Anything can be used. For example, as shown in FIG. 9, each of the two line dither data for colors other than C, M, Y, K, R, G, B is image data after dither processing using the line dither data. The screen angle may be set to 0 ° or 90 °.

  In the above-described embodiment, the line dither data for the C, M, Y, and K plates is set so that the screen line number of the image data after dither processing using the line dither data is 190 lpi. However, the present invention is not limited to this, and the number of screen lines of each of the C, M, Y, and K image data after the dither processing is arbitrary. For example, in the case of a plotter in which the dot size becomes unstable due to changes over time or environmental changes such as temperature and humidity, it is preferable to reduce the number of screen lines. In this case, for example, as shown in FIG. 10, each of the line dither data for the C, M, Y, and K plates has a screen line number of 168 lpi after image dithering using the line dither data. It may be set to be. The screen angles of the C, M, Y, and K image data after dithering are arbitrary. For example, as shown in FIG. 10, the C-type line dither data is set so that the screen angle of the image data of the C plate after dither processing using the line dither data is 34 °, and the M version The line dither data for use in the M plate is set so that the screen angle of the M image data after dithering using the line dither data is 124 °, and the line dither data for the Y plate is The screen angle of Y image data after dither processing using linear dither data is set to be 146 °, and the K line parallel dither data is obtained after dither processing using the line dither data. The screen angle of the K plate image data may be set to 56 °. In short, the line dither data for the C, M, Y, and K plates only needs to be set such that the screen angles of the C, M, Y, and K plate image data after the dither processing are different from each other. .

  In the above-described embodiment, the resolution of each plate after the dither processing is set to 600 dpi, but this is not limiting, and the value of the resolution of each plate after the dither processing is arbitrary. For example, the resolution of each plate after dithering can be set to 1200 dpi, or can be set to 2400 dpi.

  In the above-described embodiment, each of the image input device 301, the image processing device 302, and the image forming device 303 functions as an independent device. The image processing apparatus 302 may have a function of both the image processing apparatus 302 and the image processing apparatus 302, and the image forming apparatus 303 may have a function of the image processing apparatus 302. In short, the present invention can be applied to a system composed of a plurality of devices (for example, a host computer, interface device, reader, printer, etc.), or a device composed of a single device (for example, a copier, a facsimile machine, etc.). ).

  Further, the present invention supplies a program code of software that realizes the function of the image processing apparatus 302 of the above-described embodiment to a system or apparatus, and a computer (CPU or MPU) of the system or apparatus executes the program code. Can also be implemented. In this case, the program code may be supplied to the system or apparatus in a form stored in a storage medium, or may be supplied to the system or apparatus via a communication network such as the Internet. . As a storage medium for supplying the program code, for example, a flexible disk, a hard disk, an optical disk, a magneto-optical disk, a magnetic tape, a nonvolatile memory card, a ROM, or the like can be used.

  Further, when the computer executes the above-described program code, not only the functions of the image processing apparatus 302 of the above-described embodiment are realized, but also an OS ( It goes without saying that a case where the operating system) performs part or all of the actual processing and the function of the image processing apparatus 302 of the above-described embodiment is realized by the processing.

  Furthermore, after the above program code is written in the memory of the function expansion board inserted into the computer or the function expansion unit connected to the computer, the function expansion board or function expansion is performed based on the instructions of the program code. It goes without saying that a case where the CPU or the like provided in the unit performs part or all of the actual processing and the function of the image processing apparatus 302 of the above-described embodiment is realized by the processing.

  The embodiment of the present invention has been described above. The above-described embodiment shows an example of a preferred embodiment of the present invention, and the present invention is not limited thereto, and various modifications can be made without departing from the scope of the invention. is there.

DESCRIPTION OF SYMBOLS 101 Input terminal 102 Screen selection part 103 1st halftone process part 104 2nd halftone process part 105 Composition part 106 Input terminal 107 Output terminal 301 Image input device 302 Image processing apparatus 303 Image forming apparatus 310 Image formation part 401 Input terminal 402 CMYK decomposition unit 403 C version γ conversion unit 404 C version dither processing unit 405 M version γ conversion unit 406 M version dither processing unit 407 Y version γ conversion unit 408 Y version dither processing unit 409 K version γ conversion unit 410 K version dither processing Unit 411 CMYK composition unit 412 output terminal 501 input terminal 502 AB decomposition unit 503 A plate γ conversion unit 504 A plate dither processing unit 505 B plate γ conversion unit 506 B plate dither processing unit 507 input terminal 508 B plate γ setting unit 509 B Plate dither data setting unit 510 A plate γ setting unit 511 A plate dither data setting unit 512 AB composition 513 output terminal 514 AB information decomposition unit

JP 2008-14175 A

Claims (7)

A dither processing unit that performs dither processing of multi-tone input image data using dither data is provided.
The dither data is
Used for the dither processing of the input image data of the C, M, Y, and K plates, and the screen angles of the C, M, Y, and K plate image data after the dither processing are set to be different from each other. Four line dither data,
Used for the dither processing of the input image data of the R, G, and B versions, and the screen angle of each of the R, G, and B image data after the dither processing is selected from among C, M, Y, and K Three line dither data set to be the same as the screen angle of the complementary color,
Used for the dither processing of the input image data of a color plate other than C, M, Y, K, R, G, B, and other than C, M, Y, K, R, G, B after the dither processing screen angle of the image data of the color plane is seen containing C, M, Y, and two ten thousand linear dither data is set so that the angle between the screen angles of any two colors of K, the ,
The two line dither data are the first line dither data for the first color other than C, M, Y, K, R, G, B, and C, M, Y, K, R, G. , B, the second line dither data for the second color other than B,
In the first line dither data, the screen angle of the image data after the dither processing using the first line dither data does not overlap with the screen angles of C, M, Y, and K. , C, M, Y, K are set to be an angle between two screen angles corresponding to any two colors and adjacent to each other.
In the second line dither data, the screen angle of the image data after the dither processing using the second line dither data does not overlap the screen angles of C, M, Y, and K. , C, M, Y, K are set to be an angle between two screen angles corresponding to two colors different from any two colors and adjacent to each other.
An image processing apparatus. Among the four line dither data, the line dither data for the C plate is such that the screen angle of the C plate image data after dithering using the line dither data for the C plate is 18 °. The line dither data for the M plate is set so that the screen angle of the image data of the M plate after the dither processing using the line dither data for the M plate is set to 108 °. The line dither data is set so that the screen angle of Y image data after dithering using the line dither data for the Y plate is 162 °, and the line dither data for the K plate is , The screen angle of the image data of the K plate after the dither processing using the line-type dither data for the K plate is set to be 72 °,
The first line dither data is 45 ° in which the screen angle of the image data after the dither processing using the first line dither data is an angle between the C screen angle and the K screen angle. Is set to be
The second line dither data is 135 ° in which the screen angle of the image data after the dither processing using the second line dither data is an angle between the M screen angle and the Y screen angle. Set to be
The image processing apparatus according to claim 1. Among the four line dither data, the line dither data for the C plate is such that the screen angle of the C plate image data after dithering using the line dither data for the C plate is 18 °. The line dither data for the M plate is set so that the screen angle of the image data of the M plate after the dither processing using the line dither data for the M plate is set to 108 °. The line dither data is set so that the screen angle of Y image data after dithering using the line dither data for the Y plate is 162 °, and the line dither data for the K plate is , The screen angle of the image data of the K plate after the dither processing using the line-type dither data for the K plate is set to be 72 °,
The first line dither data is 0 ° in which the screen angle of the image data after the dither processing using the first line dither data is an angle between the C screen angle and the Y screen angle. Is set to be
In the second line dither data, the screen angle of the image data after the dither processing using the second line dither data is 90 ° between the K screen angle and the M screen angle. Set to be
The image processing apparatus according to claim 1. Among the four line dither data, the line dither data for the C plate is such that the screen angle of the C plate image data after dithering using the line dither data for the C plate is 34 °. The line M dither data for the M plate is set so that the screen angle of the M plate image data after dithering using the line dither data for the M plate is 124 °, and for the Y plate. The line dither data is set so that the screen angle of the Y image data after dithering using the line dither data for the Y plate is 146 °, and the line dither data for the K plate is , The screen angle of the image data of the K plate after the dither processing using the line-type dither data for the K plate is set to 56 °,
The first line dither data is 45 ° in which the screen angle of the image data after the dither processing using the first line dither data is an angle between the C screen angle and the K screen angle. Is set to be
The second line dither data is 135 ° in which the screen angle of the image data after the dither processing using the second line dither data is an angle between the M screen angle and the Y screen angle. Set to be
The image processing apparatus according to claim 1. Among the four line dither data, the line dither data for the C plate is such that the screen angle of the C plate image data after dithering using the line dither data for the C plate is 34 °. The line M dither data for the M plate is set so that the screen angle of the M plate image data after dithering using the line dither data for the M plate is 124 °, and for the Y plate. The line dither data is set so that the screen angle of the Y image data after dithering using the line dither data for the Y plate is 146 °, and the line dither data for the K plate is , The screen angle of the image data of the K plate after the dither processing using the line-type dither data for the K plate is set to 56 °,
The first line dither data is 0 ° in which the screen angle of the image data after the dither processing using the first line dither data is an angle between the C screen angle and the Y screen angle. Is set to be
In the second line dither data, the screen angle of the image data after the dither processing using the second line dither data is 90 ° between the K screen angle and the M screen angle. Set to be
The image processing apparatus according to claim 1. The number of screen lines of the color image data other than C, M, Y, K, R, G, B after the dither processing is C, M, Y, K, R, G, B after the dither processing. It is set to be higher than the screen line number of the image data.
The image processing apparatus according to claim 1, wherein the image processing apparatus is an image processing apparatus. An image forming unit that forms an image on a medium based on image data image-processed by the image processing apparatus according to any one of claims 1 to 6.
An image forming apparatus.

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