JPWO2003096675A1 - Color image forming apparatus and color image forming method - Google Patents

Abstract

A color image forming apparatus that performs smoothing of input color image data, dividing the color image data into multivalued image data representing density values for each color component, and performing smoothing among pixels in the multivalued image data The pattern of the predetermined area including the target pixel is extracted for each color component, and correction including binarization of the pattern, smoothing of the target pixel, and multi-leveling of the target pixel is enabled by an instruction from the outside In this case, the density value after correction at the target pixel is output, and when the correction is invalidated by an instruction from the outside, processing for outputting the density value before correction at the target pixel is performed for each color component, Calculate the color difference between the color tone after correction calculated from the corrected density values for all color components and the color tone before correction calculated from the density values before correction for all color components. There was an active correction if within the predetermined range, the color difference is a judgment for invalidating the correction be within a predetermined range, and instructs the result of the determination.

Description

Technical field
The present invention relates to a color image forming apparatus and a color image forming method used in a color printer which is an output device of color image data generated by a computer or the like, and more particularly to pixels (dots) generated in image formation of characters and line drawings. ), A color image forming apparatus and a color image forming method for preventing edge pseudo color generated after a smoothing process that is an image quality improving process that makes jaggy inconspicuous.
Background art
FIG. 4 is a block diagram showing a configuration example of a conventional laser printer. In the case of a color laser printer, the configuration corresponds to one color. The laser printer shown in FIG. 4 includes a main body unit 1, an image memory 12, an image development unit 13, a control circuit 14, and an optical modulation signal generation circuit 15. The main body 1 includes an optical unit 2 and an image forming unit 11. The optical unit 2 further includes a laser 3, a polygon mirror 4, a mirror motor 5, and a beam detector 6. Further, the image forming unit 11 includes a photosensitive drum 7, a developing device 8, a folding mirror 9, and a transfer roller 10.
First, the operation of the main body 1 will be briefly described. The laser 3 outputs a laser beam according to the optical modulation signal from the optical modulation signal generation circuit 15. The polygon mirror 4 is rotated by a mirror motor 5 and deflected so that the laser beam is repeatedly scanned. The beam detector 6 detects the scanning start of the scanned laser beam and outputs an optical scanning timing signal to the control circuit 14.
The surface of the photosensitive drum 7 is charged by a charger (not shown). Thereafter, the surface of the photosensitive drum 7 is irradiated with a laser beam via a folding mirror 9. The laser 3 is modulated in synchronization with the scanning of the laser beam and the rotation of the photosensitive drum 7. The surface of the photosensitive drum 7 is irradiated with an optical image corresponding to an image to be printed. The electrostatic charge charged on the surface of the photosensitive drum 7 decreases according to the irradiation amount of the laser beam. At this time, an electrostatic latent image is formed on the surface of the photosensitive drum 7. When charged toner is brought into contact with the surface of the photosensitive drum 7 by the developing unit 8, the toner adheres according to the electrostatic latent image on the surface of the photosensitive drum 7 and is visualized. The conveyed paper or the like is brought into contact with the surface of the photosensitive drum 7 on which the toner image is formed, and the toner image is transferred onto the paper by the transfer roller 10. When the transferred toner image is fixed on paper or the like by a fixing device (not shown), printing is completed. The surface of the photosensitive drum after the toner image is transferred is cleaned and then charged again, and the above process is repeated.
On the other hand, print data input from a computer system or the like is input to the image development unit 13. The control circuit 14 outputs a control clock signal generated in synchronization with the optical scanning timing signal to the image developing unit 13 and the optical modulation signal generating circuit 15. The control clock signal is a signal indicating the printing timing for each pixel. The image expansion unit 13 sequentially expands the print data into image data to be actually printed according to the control clock signal, and outputs the image data to the image memory 12. The image memory 12 stores image data. In general, the image memory 12 is called a bitmap memory. In the case of binary image data, one bit represents one pixel to be printed, and in the case of multi-value image data, a density value consisting of several bits is printed. One pixel is represented. For example, if the image data is 4 bits, 16 gradations can be expressed for each pixel, and the image memory 12 is configured to have 4 bits per pixel. The optical modulation signal generation circuit 15 sequentially reads out the image data stored in the image memory 12 according to the control clock signal, generates an optical modulation signal according to the image data, and sequentially outputs the optical modulation signal according to the control clock signal. Apply to.
In a binary printing apparatus such as a monochrome laser printer, jaggies generated in printing of characters and line drawings are automatically determined from image data developed on the image memory 12, and data having higher resolution than input image data is obtained. A smoothing process that makes jaggy inconspicuous after conversion is used in part.
FIG. 5 is a diagram illustrating an example of smoothing processing of binary image data. In FIG. 5, the vertical axis represents lines in dot units, and the horizontal axis represents pixel positions in the lines in dot units. For example, as shown in FIG. 5 (a), it is assumed that the image data stored in the image memory (image data memory) 12 has a vertical line shifted by one dot in the middle. This shifted portion is jaggy. In the smoothing process, for example, jaggy is determined by pattern matching including neighboring pixels. In the jaggy portion, the output timing of the corrected optical modulation signal is adjusted as shown in FIG. As a result, as shown in FIG. 5C, printing is performed with a half dot shift in the jaggy portion, and the vertical lines change smoothly. That is, jaggy is reduced. Here, an example of shifting by half a dot in the same direction is shown, but it is possible to shift in both the left and right directions. In other words, the smoothing process can be said to be a process in which printing can be performed at a resolution that is an integral multiple of the original image data in the main scanning direction of the laser beam, and dots are added or deleted in the jaggy portion.
FIG. 6 is a block diagram illustrating a configuration example of a conventional binary image forming apparatus that performs smoothing processing of binary image data. The optical modulation signal generation circuit 15 shown in FIG. 6 includes an image memory reading unit 16 and a smoothing circuit 17. The smoothing circuit 17 further includes a line buffer 18, an evaluation window extraction unit 21, and a correction unit 22. In FIG. 6, the same reference numerals as those in FIG. 4 denote the same or corresponding parts as those in FIG. 4, and description thereof will be omitted here.
In the image memory 12, binary image data is developed by an image developing unit (not shown). The image memory reading unit 16 reads image data of several lines before exposure with the laser 3 from the image memory 12 and transfers the image data to the line buffer 18. The line buffer 18 includes a shift register, and holds image data for several lines before and after the exposure. The evaluation window extraction unit 21 has a rectangular area (hereinafter referred to as an evaluation window) centered on one pixel (hereinafter referred to as a target pixel) 20 to be smoothed among image data held in the line buffer 18. The pixel pattern in 19 is extracted and output to the correction unit 22 as an extracted pattern arrangement signal.
The correction unit 22 has a look-up table (LUT: Look Up Table) in which a plurality of sets of patterns that can be taken by the pixels in the evaluation window and smoothing results of the target pixel corresponding to the patterns are stored in advance. The pattern stored in the lookup table is compared with the extracted pattern arrangement signal, and correction data for the target pixel stored corresponding to the matched pattern is selected. When correction is not necessary, an optical modulation signal corresponding to the original data of the target pixel is output to the optical unit 2, and when correction is required, an optical modulation signal corresponding to the correction data of the target pixel is output. Output to the optical unit 2.
FIG. 7 is a diagram showing an example of the smoothing process for the extracted pattern arrangement signal. In FIG. 7, the vertical axis represents the line in dots, and the horizontal axis represents the pixel position in the line in dots. FIG. 7A shows a pixel of line = N and pixel position = M−1 in the extracted pattern arrangement signal shown in FIG. 5A as a pixel of interest, and the pixel of interest and its surrounding pixels are 5 × 5. The pixel pattern in the evaluation window when extracted by size is shown. When the extracted pattern arrangement signal matches one of the patterns stored in the lookup table, the correction unit 22 determines that the pixel of line = N and pixel position = M−1 needs to be corrected. Correction data as shown in FIG. 7B is generated, and an optical modulation signal corresponding to the correction data is generated and output.
FIG. 7C shows a pixel of line = N, pixel position = M + 1 in the extracted pattern arrangement signal shown in FIG. 5A as a pixel of interest, and the pixel of interest and its surrounding pixels are 5 × 5. The pixel pattern in the evaluation window when extracted by size is shown. When the extracted pattern arrangement signal matches one of the patterns stored in the lookup table, the correction unit 22 determines that correction is necessary for the pixel of line = N and pixel position = M + 1, as shown in FIG. Correction data as shown in (d) is generated, and an optical modulation signal corresponding to the correction data is generated and output. Note that correction data as shown in FIG. 7D is also generated when the position of line = N and pixel = M−2 in FIG.
The smoothing circuit 17 shown in FIG. 6 outputs an optical modulation signal at the position of the target pixel when the pixels at the position corresponding to the target pixel are actually printed sequentially in synchronization with the control clock signal. A control clock signal for controlling the operation timing is generated by a control clock signal generator 23 provided in the control circuit 14. A control clock signal generation unit 23 in the control circuit 14 generates a control clock signal in synchronization with the optical scanning timing signal output from the optical unit 2 and outputs the control clock signal to the optical modulation signal generation circuit 15.
The above description is an example of correcting pixels with a double resolution in the main scanning direction, but the same applies when correcting pixels with a resolution of three times or more.
As the printing apparatus, not only a white and black binary printing apparatus but also a multi-value printing apparatus capable of expressing intermediate density pixels is provided. For example, in a laser printer as shown in FIG. 4, by controlling the light emission amount or light emission time of the laser 3 in the optical unit 2, the size of the pixels formed in the image forming unit 11 is changed and printing is equivalently performed. The density of the pixel to be changed is changed.
Next, the configuration of a multi-value laser printer that performs multi-value printing by changing the light emission amount of the laser will be described. FIG. 8 is a block diagram showing a configuration example of a multi-value laser printer. The optical modulation signal generation circuit 32 shown in FIG. 8 includes an image memory reading unit 33 and a D / A conversion unit 34. 8, the same reference numerals as those in FIG. 4 denote the same or corresponding parts as those in FIG. 4, and the description thereof will be omitted here. In the image memory 31, multivalued image data having a density is developed by an image developing unit (not shown). On the other hand, the control clock signal generation unit 36 in the control circuit 35 generates a control clock signal in synchronization with the optical scanning timing signal output from the optical unit 2 and outputs the control clock signal to the optical modulation signal generation circuit 32. The image memory reading unit 33 sequentially reads multi-value image data from the image memory 31 according to the control clock signal, and outputs the multi-value image data to the D / A conversion unit 34. The D / A converter 34 converts the digital density value in the multi-value image data into an optical modulation signal representing analog intensity, and sequentially outputs it to the optical unit 2 in accordance with the control clock signal.
A smoothing process is also performed in a laser printer that performs multi-value printing. FIG. 9 is a diagram illustrating an example of smoothing processing of quaternary image data. In FIG. 9, the vertical axis represents the line in dots, and the horizontal axis represents the pixel position in the line in dots. FIG. 9A shows an example of a pattern of quaternary image data on the image memory (image data memory). FIG. 9B shows an optical modulation signal when performing multi-value printing. FIG. 9 (c) shows the printing result.
Even when the quaternary image data smoothing process shown in FIG. 9 is performed, a smoothing circuit having a configuration similar to that shown in FIG. 6 is used, but the pixel data is multi-value data. different. Therefore, the line buffer 18 can store multi-value data, the evaluation window extraction unit 21 extracts the extracted pattern arrangement signal of the multi-value data and transfers it to the correction unit 22, and the correction unit 22 has a multi-value lookup table. There is a need. However, if the number of gradations that can be expressed in pixel units is C including white, the number of pattern combinations extracted as the evaluation window is (C / 2) in the case of binary data. ²⁵ Double. Further, since the output of the optical modulation signal also represents C densities, the size of the lookup table is further D times. D is 2 ^D-1 <C ≦ 2 ^D An integer that satisfies the condition.
As described above, when the conventional smoothing circuit is applied as it is to the smoothing processing of the multi-value image data in the multi-value printing apparatus, the size of the required lookup table becomes very large, and the creation of the table data is a pixel pattern. And the concentration thereof are complicated to create and there is a problem that it is not practical.
As a multi-value smoothing processing method for solving this problem, for example, in Japanese Patent Application No. 11-319577, as shown in FIG. 10, the input multi-value image data is decomposed into a plurality of density planes according to the density, There has been proposed a method of correcting the pixel arrangement by performing a smoothing process for each density plane and synthesizing correction values output as a result of the smoothing process for each density plane.
FIG. 10 is a block diagram showing a configuration example of a conventional multi-value image forming apparatus that performs smoothing processing of multi-value image data. The optical modulation signal generating circuit 42 shown in FIG. 10 includes an image memory reading unit 43, a smoothing circuit 44, and a D / A conversion unit 53. Further, the smoothing circuit 44 includes a density decomposition unit 45, a plane 1 correction unit 46a, a plane 2 correction unit 46b, a plane 3 correction unit 46c, and a correction value combining unit 52. Furthermore, each of the plane 1 correction unit 46 a to the plane 3 correction unit 46 c includes a line buffer 47, an evaluation window extraction unit 50, and a correction unit 51. 10, the same reference numerals as those in FIG. 4 denote the same or corresponding parts as those in FIG. 4, and the description thereof is omitted here.
Note that the laser printer including the optical modulation signal generation circuit 42 shown in FIG. 10 performs printing in four gradations including white and black in units of pixels. The image memory 41 is a 2-bit image memory. In the image memory 41, multi-valued image data is expanded in a printable state by an image expansion unit (not shown). Since three gradations can be expressed excluding white in pixel units, three density planes are prepared. Here, the density of the pixel is represented by a numerical value of 0 to 3, and the higher numerical value is the higher density. That is, density 0 corresponds to white and density 3 corresponds to black.
The control clock signal generation unit 55 in the control circuit 54 generates a control clock signal in synchronization with the optical scanning timing signal output from the optical unit 2 and outputs the control clock signal to the optical modulation signal generation circuit 42. The optical modulation signal generation circuit 42 is controlled by the control clock signal so as to output the optical modulation signal in synchronization with the progress of image writing in the main body 1.
The image memory reading unit 43 outputs the multivalued image data read from the image memory 41 to the density decomposition unit 45. The density decomposition unit 45 distributes and outputs the binarized pixel data to the plane 1 correction unit 46a to the plane 3 correction unit 46c according to a predetermined distribution rule based on the density of the multi-value image data.
Here, according to a predetermined rule used in the density decomposing unit 45, for example, pixel data is divided into a plane for each pixel density on the image memory 41 and distributed. Thus, the density 1 pixel data in the image memory 41 is distributed to the plane 1 correction unit 46a, the density 2 pixel data to the plane 2 correction unit 46b, and the density 3 pixel data to the plane 3 correction unit 46c. .
The plane 1 correction unit 46a to the plane 3 correction unit 46c perform a smoothing process on the input pixel data by the correction unit 51, and output a correction value of a corresponding level. Here, binarized pixel data is input to each of the plane 1 correction unit 46a to the plane 3 correction unit 46c. Therefore, each of the plane 1 correction unit 46a to the plane 3 correction unit 46c has the same configuration as the smoothing circuit in the conventional binary image forming apparatus, and the same correction rule can be applied. That is, the smoothing circuit 17 shown in FIG. 6 can be used as it is.
The correction values output from each of the plane 1 correction unit 46 a to the plane 3 correction unit 46 c are combined by the correction value combining unit 52 according to a predetermined combining rule and output to the D / A conversion unit 53. Here, according to a predetermined composition rule used by the correction value composition unit 52, for example, when a non-zero plane exists for the same pixel, the correction value of the plane with the highest density among such planes is output with priority. . The D / A conversion unit 53 converts the digital correction value into an optical modulation signal representing analog intensity, and sequentially outputs it to the optical unit 2 in accordance with the control clock signal.
However, in the above-described multi-level smoothing processing method, the number of gradation planes to be decomposed increases as the number of gradations is increased in order to improve the print quality by enriching the halftone expression. As a result, there arises a problem that the scale of hardware increases.
Further, when the conventional smoothing circuit is applied as it is to the smoothing processing of multi-value image data in a multi-value printing apparatus, the present applicant has solved the former problem that the size of the required lookup table becomes very large. The multi-value smoothing processing method shown in FIG. 11 has already been proposed (Japanese Patent No. 2001-235080).
FIG. 11 is a block diagram showing another configuration example of a conventional multi-value image forming apparatus that performs smoothing processing of multi-value image data. The optical modulation signal generation circuit 61 shown in FIG. 11 includes an image memory reading unit 43, a smoothing circuit 62, and a D / A conversion unit 53. Further, the smoothing circuit 62 includes a line buffer 47, an evaluation window extraction unit 50, a binarization processing unit 63, and a correction unit 64. In FIG. 11, the same reference numerals as those in FIGS. 4 and 10 denote the same or corresponding parts as those in FIGS. 4 and 10, and the description thereof is omitted here.
Note that the laser printer including the optical modulation signal generation circuit 61 shown in FIG. 11 performs printing in units of pixels, for example, with 16 gradations. Therefore, the image memory 41 is a 4-bit image memory. As shown in FIG. 11, the pixel data in the evaluation window cut out by the evaluation window extraction unit 50 is subjected to binarization processing by comparison with adjacent pixels in the binarization processing unit 63, and is sent to the correction unit 64. Is output. The correction unit 64 compares the pixel data in the binarized evaluation window with the lookup table to generate a binary LUT correction value, and finally uses this LUT correction value based on the original data. A multi-value conversion process for restoring the multi-value is performed to generate a multi-value correction value, which is output to the D / A converter 53. The D / A converter 53 converts the digital multi-value correction value into an optical modulation signal representing analog intensity, and sequentially outputs it to the optical unit 2 in accordance with the control clock signal.
Here, the binarization processing performed by the binarization processing unit 63, the LUT collation processing performed by the correction unit 64, and the multilevel conversion processing will be described with reference to the flowchart of FIG. FIG. 12 is a flowchart showing an example of binarization processing, LUT collation processing, and multilevel processing. Here, for the sake of explanation, the data of each pixel is expressed in 16 bits of 4 bits, d = 0 (white) to d = 15 (black). Further, a case where the evaluation window size is 3 and the main scanning direction is divided into 2 will be described as an example.
FIG. 13 is a diagram showing from evaluation window extraction to multilevel processing. In the evaluation window, d1 represents the density value of the target pixel, d2 represents the density value of the adjacent pixel located to the left of the target pixel, and d3 represents the density value of the adjacent pixel located to the right of the target pixel. Among the binarization evaluation window patterns, D1 indicates the density value of the pixel of interest that has been binarized. Of the LUT correction values for the pixel of interest, the left side density value is D1a and the right side density value is D1b. Of the multi-value correction values in the pixel of interest, the density value of the left part is d1a, and the density value of the right part is d1b.
First, the evaluation window extraction unit 50 extracts pixel data in the evaluation window 48 from the pixel data held in the line buffer 47 (S1). Next, the binarization processing unit 63 performs binarization processing (S2) of the pixel data in the evaluation window 48. Here, dmax indicates max (d2, d3), and dmin indicates min (d2, d3) (S21).
In step S22, it is determined whether or not dmax−d1> th. If the determination result is Yes, the process proceeds to step S4 described later. Here, th is a threshold value, for example, 2. On the other hand, if the determination result in step S22 is No, in step S23, it is determined whether d1-dmin> th. If the determination result is Yes, the process proceeds to step S5 described later. On the other hand, if the determination result of step S23 is No, the process proceeds to step S31 of step S3 described later.
In step S4, an evaluation window binarization process A shown in FIG. 14 (a) is performed. In FIG. 14 (a), step S41 sets y to y = 0, 1, 2,..., N−1, and step S42 sets x to x = 0, 1, 2,. , M−1. In step S43, it is determined whether d1 + th / 2> d (x, y). If the determination result of step S43 is Yes, step S44 sets 0 to D (x, y). On the other hand, if the determination result of step S43 is No, step S45 sets 1 to D (x, y). After step S44 or step S45, step S46 outputs x, step S47 outputs y, the process returns to the process shown in FIG. 12, and the process proceeds to step S6.
In step S5, an evaluation window binarization process B shown in FIG. 14 (b) is performed. 14B, step S51 sets y to y = 0, 1, 2,..., N−1, and step S52 sets x to x = 0, 1, 2,. , M−1. In step S53, it is determined whether or not d1-th / 2> d (x, y). If the determination result of step S53 is Yes, step S54 sets 0 to D (x, y). On the other hand, if the determination result of step S53 is No, step S55 sets 1 to D (x, y). After step S54 or step S55, step S56 outputs x, step S57 outputs y, the process returns to the process shown in FIG. 12, and the process proceeds to step S6.
FIG. 15 is a diagram showing the result of binarization processing. The pixel data in the evaluation window shown in FIG. 15 is binarized according to the binarization process described above, resulting in a binary evaluation window. The binarized density value represents either 0 = no dot or 1 = dot.
In FIG. 12, after step S4 or step S5, the correction unit 64 performs LUT collation processing (S6) for collating the binarization processing result with the lookup table. In step S7, it is determined whether there is a matching pattern as a result of the LUT matching process. If the determination result of step S7 is No, it will transfer to step S31 of step S3 mentioned later. On the other hand, if the determination result of step S7 is Yes, it will transfer to step S32 of step S3 mentioned later.
Next, the correction unit 64 performs multilevel processing (S3). The multi-value processing is the same as the conventional optical modulation signal correction method in FIGS. 6 and 7. However, since the correction data in FIGS. 6 and 7 is binary data, it is converted to multi-value again. Convert. As the multi-value processing, there are two methods, for example, a simple replacement process shown in FIG. 16 and an averaging process shown in FIG. In each multi-value processing, the simple replacement processing has a feature that the corrected edge remains sharp, and the averaging processing has a smooth edge after correction.
First, the simple replacement process shown in FIG. 16 will be described. In the simple replacement process, when D1 = 1, 1 is converted into original data d1 in D1a or D1b, and 0 is converted into adjacent data in D1a or D1b. This is indicated by the processing in step S33 described later. That is, D1a × d1 + D1a ′ × d2 is set to d1a, and D1b × d1 + D1b ′ × d3 is set to d1b (S33). Here, “′” means inversion. FIG. 16 (a) is a diagram showing an example in which multilevel processing is performed using simple replacement processing when D1 = 1.
In the simple replacement process, when the density value D1 = 0 of the target pixel, 0 is converted into the original data d1 in D1a or D1b, and 1 is converted into adjacent data in D1a or D1b. This is indicated by the processing in step S34 described later. That is, D1a ′ × d1 + D1a × d2 is set to d1a, and D1b ′ × d1 + D1b × d3 is set to d1b (S34). FIG. 16 (b) is a diagram showing an example in which multilevel processing is performed using simple replacement processing when D1 = 0.
Next, the averaging process shown in FIG. 17 will be described. In the averaging process, when D1 = 1, 1 is converted into the original data d1 in D1a or D1b, and 0 is converted into an intermediate value with the adjacent data in D1a or D1b. FIG. 17 (a) is a diagram showing an example in which multilevel processing is performed using averaging processing when D1 = 1.
In the averaging process, when D1 = 0, 0 is converted into the original data d1 in D1a or D1b, and 1 is converted into an intermediate value with the adjacent data in D1a or D1b. FIG. 17B is a diagram showing an example in which multilevel processing is performed using averaging processing when D1 = 0.
In the flowchart of FIG. 12, the multi-value process (S3) will be described using the above-described simple replacement process. In step S32, it is determined whether or not D1 = 1. If the determination result in step S32 is Yes, the process shown in step S33 is performed, and this flowchart ends. On the other hand, if the determination result of step S32 is No, the process shown in step S34 is performed, and this flowchart is ended. On the other hand, in step S31, d1 is set to d1a, d1 is set to d1b, and this flowchart is ended. By performing the above processing in the binarization processing unit 63 and the correction unit 64, multi-level smoothing processing is performed.
FIG. 18 is a diagram showing a configuration example of a color laser printer using the conventional multi-value image forming apparatus shown in FIG. As shown in FIG. 18, the color laser printer includes four image memories 41a to 41d, four optical modulation signal generation circuits 61a to 61d, four optical units 2a to 2d, and four image forming units 11a. To 11d, a control circuit 54, and an image development unit 71. Each of the optical modulation signal generation circuits 61a to 61d has the same configuration as that of the optical modulation signal generation circuit 61 shown in FIG. The optical units 2a to 2d and the image forming units 11a to 11d have the same configurations as the optical unit 2 and the image forming unit 11 shown in FIG.
That is, the image memory 41, the optical modulation signal generation circuit 61, the optical unit 2, and the image forming unit 11 shown in FIG. 11 are connected to each color plane, C (cyan), M (magenta), Y (yellow), Provided for each of the K (black) components. In the above description of the smoothing circuit, the K component has been described, but the same processing is performed for the C component, the M component, and the Y component.
The input print data is input to the image development unit 71. The image development unit 71 develops the print data into color image data, divides the color image data into multi-value image data for each color plane, and sequentially outputs the C component multi-value image data to the image memory 41a in accordance with the control clock signal. The multi-value image data of M component is output to the image memory 41b, the multi-value image data of Y component is output to the image memory 41c, and the multi-value image data of K component is output to the image memory 41d.
The C component multivalued image data in the image memory 41a is processed by the optical modulation signal generation circuit 61a, the optical unit 2a, and the image forming unit 11a. Similarly, the M component multi-valued image data in the image memory 41b is processed by the optical modulation signal generation circuit 61b, the optical unit 2b, and the image forming unit 11b, and the Y component multi-valued image data in the image memory 41c is optically modulated. The signal generation circuit 61c, the optical unit 2c, and the image forming unit 11c process the multi-valued image data of the K component in the image memory 41d, and the optical modulation signal generation circuit 61d, the optical unit 2d, and the image forming unit 11d process. Each of the optical units 2 a to 2 d outputs an optical scanning timing signal to the control circuit 54. The control circuit 54 controls the optical modulation signal generation circuits 61a to 61d. With the above configuration, the multi-value image forming apparatus shown in FIG. 11 can be applied to a color laser printer.
However, when the multi-value image forming apparatus shown in FIG. 11 is applied to a color laser printer, a multi-value smoothing process is performed independently for each color, so that a difference occurs in the correction amount for each color, and as a result, There arises a problem that an edge pseudo color that should not originally exist in the edge portion may occur.
The present invention has been made to solve such a problem. Color and multi-value conversion is performed without increasing the size of a required lookup table, and an edge pseudo color generated after the smoothing process is further provided. An object of the present invention is to provide a color image forming apparatus and a color image forming method capable of performing smoothing processing of a multi-valued color image by preventing the above.
Disclosure of the invention
The present invention is a color image forming apparatus that performs smoothing of input color image data, the image developing means for dividing the color image data into multi-value image data representing density values for each color component, and color components Image storage means for storing multivalued image data representing density values for each color; and extracting a pattern of a predetermined region including a target pixel to be smoothed among pixels in the multivalued image data for each color component Evaluation window extraction means, binarization processing means for each color component for binarizing the pattern as presence / absence of dots, smoothing of the pixel of interest based on the binarized pattern, and When the smoothing result is multi-valued and the correction including the binarization, the smoothing, and the multi-value conversion is validated by an instruction from the outside, A correction unit for each color component that outputs a density value after correction in an element, and outputs the density value before correction in the target pixel when the correction is invalidated by an external instruction; Calculate the color difference between the corrected color tone calculated from the corrected density values of all the color components and the color tone before correction calculated from, for example, the density values before correction of all the color components. If the color difference is within a predetermined range, the correction is validated. If the color difference is not within the predetermined range, the correction is invalidated. The result of the determination is sent to the correction unit as the instruction. And a determination means for outputting.
According to such a configuration, by converting to binary image data and performing smoothing, it can be realized with a small circuit even if the number of gradations is increased, and the validity of the correction can be determined based on the color difference. By doing so, it is possible to prevent the generation of edge pseudo color associated with the use of binary image data.
Further, in the color image forming apparatus according to the present invention, the determination unit includes a corrected color element that is projected on the ab plane, the corrected color tone expressed in the Lab space, and the uncorrected color element that is expressed in the Lab space. A color element before correction obtained by projecting a color tone onto an ab plane is used, and the color difference is a distance between the color element after correction and the color element before correction.
According to such a configuration, it is possible to prevent the occurrence of edge pseudo colors having greatly different color elements in smoothing by determining the effectiveness of correction using color elements.
In the color image forming apparatus according to the present invention, the binarization processing unit compares the density value of the target pixel to be binarized with the density value of at least one pixel adjacent to the target pixel. And the density value in the target pixel is binarized based on the result of the comparison.
According to such a configuration, by comparing the pixel of interest in the multi-valued image data with the surrounding pixels, it is possible to convert the edge to be smoothed into binary image data that appropriately represents, Restoration to multi-value image data can be facilitated.
In the color image forming apparatus according to the present invention, the correction unit includes a look-up table in which a plurality of sets of patterns that can be taken by the region and smoothing results of the target pixel corresponding to the patterns are stored in advance. In the smoothing, the pattern stored in the lookup table is compared with the pattern output by the evaluation window extraction unit, and the smoothing result of the target pixel stored in the lookup table corresponding to the matched pattern is obtained. It is characterized by outputting.
According to such a configuration, by using a binary look-up table, it can be realized with a small circuit even if the number of gradations is increased.
Further, in the color image forming apparatus according to the present invention, in the multi-value conversion, when the pixel of interest subjected to the binarization has a dot, a portion expressed by the smoothing as having a dot is a correction of the pixel of interest. The previous density value, the portion expressed as no dot by the smoothing is converted into the density value of the pixel adjacent to the portion, and when the pixel of interest subjected to the binarization is dotless, there is no dot by the smoothing Is converted to a density value before correction of the pixel of interest, and a part expressed by the smoothing is converted to a density value of an adjacent pixel.
Further, in the color image forming apparatus according to the present invention, in the multi-value conversion, when the pixel of interest subjected to the binarization has a dot, a portion indicated by the smoothing as having a dot is corrected for the pixel of interest. The previous density value, the portion represented as no dot by the smoothing is converted to an intermediate value between the density value of the pixel adjacent to the portion and the density value before correction of the target pixel, and the binarization is performed. When the pixel of interest has no dots, the portion represented as having no dots by the smoothing is the density value before correction of the pixel of interest, and the portion represented by the smoothing is having the density value of the pixel adjacent to the portion. The pixel value is converted into an intermediate value of the density value before correction of the target pixel.
According to such a configuration, appropriate restoration of binarized multi-valued image data can be easily performed by using pixels adjacent to the pixel of interest in the multi-valued image data.
The present invention is also a color image forming method for performing smoothing of input color image data, wherein the color image data is divided into multi-value image data representing density values for each color component, and Storing multi-value image data representing density values, extracting a pattern of a predetermined region including a target pixel to be smoothed from pixels in the multi-value image data for each color component, and Is binarized as the presence / absence of each color component, and based on the binarized pattern, the pixel of interest is smoothed and the result of the smoothing is multivalued, and the binarization and the binarization are performed. When the correction including smoothing and multi-value conversion is validated by an instruction from the outside, the corrected density value at the target pixel is output, and the correction is performed by an instruction from the outside. In the case of being effective, the process of outputting the density value before correction in the target pixel is performed for each color component, for example, after the correction calculated from the density values after correction in all the color components Calculate the color difference between the color tone and the color tone before correction calculated from the density value before correction in all the color components, for example, if the color difference is within a predetermined range, the correction is enabled, If the color difference is not within a predetermined range, it is determined that the correction is invalidated, and the result of the determination is used as the instruction.
In the color image forming method according to the present invention, the determination may be performed by correcting the corrected color tone expressed in the Lab space on the ab plane and the corrected color tone expressed in the Lab space. And the uncorrected color element projected on the ab plane, and the color difference is a distance between the corrected color element and the uncorrected color element.
In the color image forming method according to the present invention, the binarization is performed by comparing a density value in the target pixel to be binarized with a density value in at least one pixel adjacent to the target pixel. Based on the result of the comparison, the density value in the target pixel is binarized.
In the color image forming method according to the present invention, the smoothing may be performed using a look-up table in which a plurality of sets of patterns that can be taken by the region and smoothing results of the target pixel corresponding to the pattern are stored in advance. A pattern stored in an up-table is compared with a pattern output from the evaluation window extracting means, and a smoothing result of the pixel of interest stored in the look-up table corresponding to the matched pattern is output. It is what.
Further, in the color image forming method according to the present invention, in the multi-value conversion, when the pixel of interest subjected to the binarization has a dot, a portion expressed by the smoothing as having a dot is corrected for the pixel of interest. The previous density value, the portion expressed as no dot by the smoothing is converted into the density value of the pixel adjacent to the portion, and when the pixel of interest subjected to the binarization is dotless, there is no dot by the smoothing Is converted to a density value before correction of the pixel of interest, and a part expressed by the smoothing is converted to a density value of an adjacent pixel.
Further, in the color image forming method according to the present invention, in the multi-value conversion, when the pixel of interest subjected to the binarization has a dot, a portion indicated as having a dot by the smoothing is corrected for the pixel of interest. The previous density value, the portion represented as no dot by the smoothing is converted to an intermediate value between the density value of the pixel adjacent to the portion and the density value before correction of the target pixel, and the binarization is performed. When the pixel of interest has no dots, the portion represented as having no dots by the smoothing is the density value before correction of the pixel of interest, and the portion represented by the smoothing is having the density value of the pixel adjacent to the portion. The pixel value is converted into an intermediate value of the density value before correction of the target pixel.
BEST MODE FOR CARRYING OUT THE INVENTION
Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. FIG. 1 is a block diagram showing a structural example of a color image forming apparatus of the present invention. The optical modulation signal generation circuit 81 shown in FIG. 1 includes an image memory reading unit 43, a smoothing circuit 82, and a D / A conversion unit 53. Further, the multilevel smoothing circuit 82 includes a line buffer 47, an evaluation window extraction unit 50, a binarization processing unit 63, and a correction unit 83. Further, a color tone comparison unit 84 connected to the correction unit 83 and the image memory 41 is provided. In FIG. 1, the same reference numerals as those in FIGS. 4 and 11 denote the same or corresponding parts as those in FIGS. 4 and 11, and the description thereof is omitted here.
FIG. 2 is a diagram showing a configuration example of a color laser printer using the color image forming apparatus of the present invention. As shown in FIG. 2, the color laser printer includes four image memories 41a to 41d, four optical modulation signal generation circuits 81a to 81d, four optical units 2a to 2d, and four image forming units 11a. To 11d, a control circuit 54, an image development unit 71, and a color tone comparison unit 84. Each of the optical modulation signal generation circuits 81a to 81d has the same configuration as the optical modulation signal generation circuit 81 shown in FIG. The optical units 2a to 2d and the image forming units 11a to 11d have the same configurations as the optical unit 2 and the image forming unit 11 shown in FIG. That is, the image memory 41, the optical modulation signal generation circuit 81, the optical unit 2, and the image forming unit 11 shown in FIG. 1 are provided for each of the color planes, C, M, Y, and K components. 2, the same reference numerals as those in FIGS. 4 and 18 denote the same or corresponding parts as those shown in FIGS. 4 and 18, and the description thereof will be omitted here.
In the present embodiment, the image expansion means corresponds to the image expansion section 71, the image storage means corresponds to the image memory 41, the image memory reading section 43, and the line buffer 47, and the evaluation window extraction means corresponds to the evaluation window extraction section. 50, the binarization processing unit corresponds to the binarization processing unit 63, the correction unit corresponds to the correction unit 83, and the determination unit corresponds to the color tone comparison unit 84.
Hereinafter, the correction unit 83 and the color tone comparison unit 84 will be described with reference to the flowchart of FIG. FIG. 3 is a flowchart showing an example of binarization processing, LUT collation processing, multi-level processing, and color tone comparison. In FIG. 3, the same reference numerals as those in FIG. 12 denote the same processes as those in FIG. 12, and the description thereof is omitted here. First, the color tone comparison unit 84 calculates the color tone by color-combining the corrected C′M′Y′K ′ values obtained from the optical modulation signal generation circuits 81a to 81d for the respective colors, and the image memory 41a for each color. The color tone is calculated by color synthesis of the CMYK values before correction obtained from .about.41d (S8), and the process proceeds to step S9.
Next, the color tone comparison unit 84 performs color tone comparison. First, in step S9, a color difference between a color tone before correction and a color tone after correction is calculated, and it is determined whether the color difference is equal to or greater than a set value. Here, the setting value is 1, for example. If the color difference is equal to or larger than the set value according to the determination result of step S9, it is determined that the edge pseudo color is generated, and the process proceeds to step S10, where the color tone comparison unit 84 discards the corrected C′M′Y′K ′ value and corrects it. A control signal is output to the correction unit 83 for each color so as to output the previous CMYK value. That is, in step S10, d1 is set to d1a, d1 is set to d1b, and this flowchart is ended. On the other hand, if the color difference is less than the set value according to the determination result of step S9, the color tone comparing unit 84 outputs a control signal to the correcting unit 83 for each color so that the corrected C′M′Y′K ′ value is output as it is. .
In color tone comparison, a change in brightness is not easily recognized as an edge pseudo color, and a change in color element is likely to be a problem. Therefore, it is desirable to define the change in color element. For example, conversion from CMYK space to Lab space is performed, and the amount of change in ab coordinates is compared. Here, the color tone before correction converted from the CMYK space to the Lab space is expressed as Lab, and the color tone after correction is expressed as L′ a′b ′. When each of them is projected on the ab plane, the change amount of the ab coordinate is { (Aa ') ² + (B−b ′) ² } ^1/2 It is represented by
By adopting the above configuration, color / multi-value can be obtained without increasing the scale as compared with a lookup table applied to a conventional monochrome binary printer, and edge pseudo color generated after smoothing processing can be prevented. It becomes possible.
In the above embodiment, the present invention is applied to the laser printer, but it goes without saying that the present invention can be applied to LED printers, inkjet printers, and displays as well.
Industrial applicability
As described above, according to the present invention, in a color image forming apparatus for forming a multi-valued color image, a necessary lookup table equivalent to a binary printer can be used, which occurs during image formation. Smoothing processing that makes jaggies to be inconspicuous and the generation of edge pseudo color associated therewith can be prevented. That is, a smoothing process for forming a multi-valued color image with a simple configuration and low cost can be realized.
Also, even if the number of gradations is increased to improve the image quality of photographic images, smoothing processing can be performed without increasing the hardware scale. Conventional techniques can be used as they are.
[Brief description of the drawings]
FIG. 1 is a block diagram showing a structural example of a color image forming apparatus of the present invention.
FIG. 2 is a diagram showing a configuration example of a color laser printer using the color image forming apparatus of the present invention.
FIG. 3 is a flowchart showing an example of binarization processing, LUT collation processing, multi-level processing, and color tone comparison.
FIG. 4 is a block diagram showing a configuration example of a conventional laser printer.
FIG. 5 is a diagram illustrating an example of smoothing processing of binary image data.
FIG. 6 is a block diagram illustrating a configuration example of a conventional binary image forming apparatus that performs smoothing processing of binary image data.
FIG. 7 is a diagram showing an example of the smoothing process for the extracted pattern arrangement signal.
FIG. 8 is a block diagram showing a configuration example of a multi-value laser printer.
FIG. 9 is a diagram illustrating an example of smoothing processing of quaternary image data.
FIG. 10 is a block diagram showing an example of the configuration of a conventional multi-value image forming apparatus that performs multi-value image data smoothing processing.
FIG. 11 is a block diagram illustrating another configuration example of a conventional multi-value image forming apparatus that performs smoothing processing of multi-value image data.
FIG. 12 is a flowchart showing an example of binarization processing, LUT collation processing, and multilevel processing.
FIG. 13 is a diagram showing from evaluation window extraction to multilevel processing.
FIG. 14 is a flowchart showing an example of evaluation window binarization processing A and evaluation window binarization processing B.
FIG. 15 is a diagram showing the result of binarization processing.
FIG. 16 is a diagram showing an embodiment in which a simple replacement process is used as the multi-value process.
FIG. 17 is a diagram showing an example in which an averaging process is used as the multi-value process.
FIG. 18 is a diagram showing the configuration of a color printer using the conventional multi-value image forming apparatus shown in FIG.

Claims (12)

A color image forming apparatus that performs smoothing of input color image data,
Image development means for dividing the color image data into multivalued image data representing density values for each color component;
Image storage means for storing multivalued image data representing density values for each color component;
An evaluation window extracting unit for each color component that extracts a pattern of a predetermined region including a target pixel to be smoothed among pixels in the multi-valued image data;
Binarization processing means for each color component for binarizing the pattern as the presence or absence of dots;
Based on the binarized pattern, the pixel of interest is smoothed and the result of the smoothing is multivalued, and the correction including the binarization, the smoothing, and the multivalue is effective by an instruction from the outside The corrected density value in the target pixel is output, and when the correction is invalidated by an external instruction, the uncorrected density value in the target pixel is output. Correction means for each color component;
Calculating a color difference between a corrected color tone calculated from the corrected density value of the color component and a color tone before correction calculated from the density value of the color component before correction; and Determining means for validating the correction if within a predetermined range, invalidating the correction if the color difference is not within the predetermined range, and outputting the result of the determination to the correcting means as the instruction; ,
A color image forming apparatus comprising: In the color image forming apparatus according to claim 1,
The determination means includes a corrected color element in which the corrected color tone expressed in Lab space is projected on the ab plane, and a color before correction in which the uncorrected color tone expressed in Lab space is projected on the ab plane. The color image forming apparatus is characterized in that the color difference is a distance between the corrected color element and the uncorrected color element. In the color image forming apparatus according to claim 1,
The binarization processing unit compares the density value of the target pixel to be binarized with the density value of at least one pixel adjacent to the target pixel, and based on the result of the comparison, A color image forming apparatus characterized in that a density value in a pixel is binarized. In the color image forming apparatus according to claim 1,
The correction means includes a look-up table in which a plurality of sets of patterns that can be taken by the region and smoothing results of the pixel of interest corresponding to the pattern are stored in advance, and the smoothing is a pattern stored in the look-up table. And a pattern output from the evaluation window extracting means, and a smoothing result of the pixel of interest stored in the look-up table corresponding to the matched pattern is output. In the color image forming apparatus according to claim 1,
In the multi-value conversion, when the pixel of interest subjected to the binarization has a dot, a portion expressed as having a dot by the smoothing is expressed as a density value before the correction of the pixel of interest, and no dot by the smoothing. The converted portion is converted into a density value of a pixel adjacent to the portion, and when the binarized pixel of interest has no dots, the portion represented by the smoothing as having no dots is the pixel before correction of the pixel of interest. A color image forming apparatus characterized in that a density value of a pixel and a portion represented by a dot by smoothing are converted into a density value of an adjacent pixel. In the color image forming apparatus according to claim 1,
In the multi-value quantization, when the pixel of interest subjected to the binarization has a dot, a portion represented as having a dot by the smoothing represents a density value before correction of the pixel of interest, and a dot having no dot by the smoothing. The converted portion is converted into an intermediate value between a density value of a pixel adjacent to the portion and a density value before correction of the target pixel, and when the target pixel subjected to the binarization has no dot, a dot is generated by the smoothing. The portion represented as absent is the density value before correction of the pixel of interest, and the portion represented by the smoothing as dot is the intermediate value between the density value of the pixel adjacent to the portion and the density value of the pixel of interest before correction A color image forming apparatus characterized by converting into a color image. A color image forming method for smoothing input color image data,
The color image data is divided into multi-value image data representing density values for each color component,
Multi-value image data representing density values for each color component is stored,
Extracting a pattern of a predetermined area including a target pixel to be smoothed among pixels in the multi-value image data for each color component,
Binarization expressing the pattern as presence / absence of dots is performed for each color component;
Based on the binarized pattern, the pixel of interest is smoothed and the result of the smoothing is multivalued, and the correction including the binarization, the smoothing, and the multivalue is effective by an instruction from the outside If the correction is invalidated by an instruction from the outside, a process of outputting the pre-correction density value for the target pixel is output. For each color component,
Calculating a color difference between a corrected color tone calculated from the corrected density value of the color component and a color tone before correction calculated from the density value of the color component before correction; and Color image formation, wherein the correction is validated if it is within a predetermined range, and the correction is invalidated if the color difference is not within the predetermined range, and the result of the determination is used as the instruction Method. The color image forming method according to claim 7,
The determination is performed by projecting the corrected color tone expressed in the Lab space onto the ab plane, and the color element before correction expressed in the Lab space and projected on the ab plane. And the color difference is a distance between the corrected color element and the uncorrected color element. The color image forming method according to claim 7,
In the binarization, the density value in the target pixel to be binarized is compared with the density value in at least one pixel adjacent to the target pixel, and the target pixel is compared based on the comparison result. A color image forming method, wherein density values are binarized. The color image forming method according to claim 7,
The smoothing uses a look-up table in which a plurality of sets of patterns that can be taken by the region and smoothing results of the target pixel corresponding to the pattern are stored in advance, and the pattern stored in the look-up table and the evaluation window extraction A color image forming method characterized in that the pattern output by the means is collated and the smoothing result of the pixel of interest stored in the look-up table corresponding to the matched pattern is output. The color image forming method according to claim 7,
In the multi-value conversion, when the pixel of interest subjected to the binarization has a dot, a portion expressed as having a dot by the smoothing is expressed as a density value before the correction of the pixel of interest, and no dot by the smoothing. The converted portion is converted into a density value of a pixel adjacent to the portion, and when the binarized pixel of interest has no dots, the portion represented by the smoothing as having no dots is the pixel before correction of the pixel of interest. A color image forming method, wherein the density value of the pixel and the portion represented by the smoothing as a dot are converted to the density value of an adjacent pixel. The color image forming method according to claim 7,
In the multi-value quantization, when the pixel of interest subjected to the binarization has a dot, a portion represented as having a dot by the smoothing represents a density value before correction of the pixel of interest, and a dot having no dot by the smoothing. The converted portion is converted into an intermediate value between a density value of a pixel adjacent to the portion and a density value before correction of the target pixel, and when the target pixel subjected to the binarization has no dot, a dot is generated by the smoothing. The portion represented as absent is the density value before correction of the pixel of interest, and the portion represented by the smoothing as dot is the intermediate value between the density value of the pixel adjacent to the portion and the density value of the pixel of interest before correction A color image forming method characterized by converting into a color image.

Images