JP3732542B2 - Image processing device - Google Patents

Description

[0001]
[Industrial application fields]
The present invention relates to an image processing apparatus that performs various editing processes on an image and outputs the processed image.
[0002]
[Prior art]
2. Description of the Related Art Conventionally, in color copiers and color FAX apparatuses, there are known image processing apparatuses that perform various types of image processing in accordance with the type of document and the type of each image area and then output from an image output unit. In this image processing apparatus, a processing module is prepared for each image processing applied to image data. Each processing module includes the type of area to be processed (black characters, color characters, intermediate chroma characters, design), document type (standard, characters, photograph, map), output color (monocolor, B / W, 3 Individual control signals are supplied in accordance with color colors, four color colors, and the like. This is because each processing module performs different image processing and needs to use a unique coefficient. In each processing module, image processing is performed based on the coefficients corresponding to the individual control signals described above.
[0003]
For example, Japanese Patent Laid-Open No. 5-037776 discloses the above-described image processing apparatus. In this image processing apparatus, region signals are supplied to each processing module, for example, a scaling processing unit, a processing processing unit, a memory, a first filter, a first γ conversion unit, and the like. Actually, various control signals corresponding to each processing module are supplied in addition to the area signal. Japanese Patent Application Laid-Open No. 5-048892 also discloses a similar image processing apparatus, and an individual judgment unit corresponding to each processing module is used by a comprehensive judgment circuit according to the color of the original image data and characters. A control signal is supplied.
[0004]
FIG. 7 is a block diagram showing a schematic configuration of the above-described conventional image processing apparatus. In the figure, each processing module 1, 2, 3, 4 performs individual image processing in accordance with control signals S1, S2, S3, S4 supplied from a control signal generator (not shown). Each of the processing modules 1 to 4 sequentially performs image processing on the processed image data when the image processing by the previous processing module is completed. Therefore, it is necessary to synchronize the timing at which the control signals S2, S3, and S4 are supplied to the timing at which the image processing by the preceding processing module is completed and output to the subsequent processing module. Therefore, in the illustrated example, delay means 5, 6, and 7 are inserted in signal lines to which the control signals S2, S3, and S4 are supplied. The delay time of each of the delay means 5, 6 and 7 is set according to the processing time required for image processing by the preceding processing module.
[0005]
[Problems to be solved by the invention]
By the way, the conventional image processing apparatus described above has a drawback in that the number of signal lines increases because individual control lines are used for each processing module. Further, in recent advanced image processing apparatuses, the number of control signals for changing image processing conditions has increased considerably in order to reproduce an original more faithfully and to obtain an image desired by an operator. is doing. However, since individual control lines are used for each processing module, there is a problem that the number of signal lines increases and the circuit scale increases.
[0006]
Further, since individual control lines are used for each processing module, the position of the processing module cannot be changed without changing the wiring. Therefore, since the position of each module is fixed, the processing contents cannot be made flexible, for example, by changing the processing sequence. That is, when the processing contents are changed due to a design change or the like, the position of each processing module is fixed, so that there is a problem that the system design including the wiring and the like has to be performed again from the beginning.
[0007]
The present invention has been made in view of the above-described circumstances, and an image processing apparatus capable of reducing the circuit scale and reducing the cost without increasing the circuit scale even when the number of processing modules increases considerably. It is intended to provide.
[0008]
[Means for Solving the Problems]
In order to solve the above-described problems, in the invention according to claim 1,In an image processing apparatus including a plurality of image processing units that perform image processing on image data,A control signal representing the content of image processing performed on image dataA control signal encoding unit that outputs an encoded signal common to the plurality of image processing units,Each of the image processing units, decoding means for decoding the encoded signal supplied from the control signal encoding unit into a control signal according to the unique image processing,EnteredImage processing means for decoding the image data by the decoding means and performing image processing based on a control signal.
[0009]
In the invention according to claim 2,The image processing unit adjusts the time required from the supply of image data to the output to the image processing unit to output the image processing unit.Each of the plurality of image processing units has a delay unit that is the same.
[0011]
[Action]
According to this invention,Each image processing unit is supplied with image data for performing image processing and an encoding control signal representing the contents of image processing for the image data.
Each image processing unit decodes the input encoding control signal, performs image processing corresponding to the decoded control signal on the input image data, and outputs the processed image data.
As described above, since the control signal representing the processing contents is encoded, even when the circuit scale is reduced and the number of processing modules is increased, the cost can be reduced without increasing the circuit scale. .
[0012]
【Example】
Next, an embodiment of the present invention will be described with reference to the drawings.
A. Example configuration
A-1. Common configuration
FIG. 1 is a diagram showing a schematic configuration of an image processing apparatus according to an embodiment of the present invention. In the following description, the case where the present invention is applied to a color copying machine will be described. However, the present invention is not limited to this and can be applied to a color FAX apparatus or the like. In FIG. 1, a base machine 30 includes a platen glass 31 on which an original is placed, an image input terminal 32, an electric system control storage unit 33, an image output terminal 34, a paper tray 35, a user interface 36, an edit pad 61, an auto pad 61, The apparatus includes a document feeder 62, a sorter 63, and a film image reading device including a film projector 64 and a mirror unit 65.
[0013]
The image input terminal 32 includes an imaging unit 37, a wire 38 for driving the imaging unit 37, a drive pulley 39, and the like. The color filter in the imaging unit 37 separates the light into the three primary colors B, G, and R, and the CCD. Image information of a color original read by using a line sensor is converted into multi-gradation digital image data B, G, R and output to an image processing system. The image processing system is stored in the electric system control storage unit 33, and inputs image data of the three primary colors B, G, and R to improve color, gradation, definition, other image quality, reproducibility, and the like. Various conversions, corrections, and editing processes are performed. The toners are converted into toner primary colors Y, M, C, and K, and the process color gradation toner signal is turned on / off. It is converted into a valued toner signal and output to the image output terminal 34.
[0014]
The electric system control storage unit 33 includes a plurality of control boards configured separately for each processing unit such as the image input terminal 32, the image output terminal 34, a user interface 36, an image processing system, a film projector 64, and the like described above, Furthermore, a circuit board for controlling the operation of mechanisms such as the image output terminal 34, the auto document feeder 62, the sorter 63 and the like, and a circuit board for controlling the whole are accommodated.
[0015]
The image output terminal 34 includes a scanner 40 and a photosensitive belt 41. The laser output unit 40a converts image data into an optical signal, and the image output terminal 34 senses through the polygon mirror 40b, the F / Θ lens 40c, and the reflection mirror 40d. A latent image corresponding to the original image is formed on the material belt 41, the image is transferred to the paper conveyed from the paper tray 35, and the color copy is discharged. In the image output terminal 34, the photosensitive belt 41 is driven by a drive pulley 41a, and a cleaner 41b, a charger 41c, YMCK developing units 41d, and a transfer unit 41e are arranged around the belt 41a. Thus, a transfer device 42 is provided. Then, the paper fed from the paper tray 35 through the paper conveyance path 35a is added, and in the case of four-color full-color copying, the YMCK latent images are transferred onto the paper by rotating the transfer device 42 four times. Then, the paper is fixed by the fixing device 45 from the transfer device 42 through the vacuum conveying device 43 and discharged. An SSI (single sheet inserter) 35b selectively supplies paper to the paper conveyance path 35a manually.
[0016]
The user interface 36 is for selecting a function desired by the user and instructing its execution condition. The user interface 36 includes a color CRT display 51 and a hardware control panel 52, and further combines an infrared touch board 53 to display a screen. It can be instructed directly with a soft button.
[0017]
B. Example 1
B-1. Block configuration of the first embodiment
FIG. 2 is a block diagram showing the configuration of the first embodiment of the present invention. In FIG. 2, the image input means 101 includes a reduction type line sensor including, for example, three CCD line sensors B, G, and R arranged at right angles to the sub-scanning direction. The image is read by scanning in the main scanning direction while moving at a speed corresponding to the magnification. The read B, G, R image data is converted into digital image data of a predetermined number of bits, for example, 8 bits by an A / D converter (not shown). This makes it possible to express 256 levels of gradation for each color.
[0018]
The color space conversion means 102 is designed to improve the color, gradation, definition, other image quality, reproducibility, etc. of the 8-bit digital image data of B, G, R supplied from the image input means 101. Various conversion and correction processes are performed, and digital image data is converted into toner primary colors Y, M, and C. The under color removal / black generation and data selection unit 103 first performs under color removal and black generation for the Y, M, and C signals converted by the color space conversion unit 102 by the under color removal / black generation unit. Apply. Next, the data selection means of the under color removal / black generation and data selection means 103 sequentially selects the Y, M, C, and K signals subjected to the under color removal and black generation, and supplies them to the filter 105 for each color. Supply. Here, the order of colors to be output is not particularly defined.
[0019]
The filter 105 emphasizes an edge in the case of a character or the like according to the supplied image, performs a smoothing process in the case of a pattern or the like, and supplies it to the coloring processing means 106. The filter 105 can switch coefficients used for processing according to the characteristics of the image data, and includes four (four types) coefficients. The coloring processing unit 106 performs coloring when the image data is subjected to coloring processing, and supplies the image data to the γ conversion unit 107. The coloring processing unit 106 can switch the coefficients used for processing according to the characteristics of the image data, and has four (four types) coefficients. The γ conversion means 107 performs γ conversion suitable for the character mode, the picture mode, etc., and supplies it to the image commission output means 108. The γ conversion means 107 can switch coefficients used for processing according to the characteristics of the image data, and is provided with coefficients for eight surfaces (eight types). Next, based on the B, G, and R signals read by the image input unit 101, the region discriminating unit 109 determines, for each pixel, whether the pixel is a character / color character / intermediate chroma character / pattern region. And the determination result is supplied to the control signal encoding means 112 as a 2-bit discrimination signal, for example.
[0020]
The document type instructing unit 110 is a partial function of the user interface 36 shown in FIG. 1 described above, and is operated by an operator or the like, for example, 2 types to output image data in standard / character / photo / map. The signal is supplied to the control signal encoding means 112 as a bit (one of four) instruction signal. The mono-color designating unit 111 is a partial function of the user interface 36 shown in FIG. 1 and is operated by an operator or the like to process image data in mono-color, B / W, three-color, four-color. Which mode is to be output as, for example, a 2-bit (1 out of 4) instruction signal, and when selecting a mono color, the output color is, for example, a 4-bit (1 out of 16 colors) instruction signal As a result, a total 6-bit instruction signal is supplied to the control signal encoding means 112.
[0021]
Next, the control signal encoding unit 112 includes the above-described area determination unit 109, document type instruction unit 110, andMonochromatic color designation means 11110-bit control signals supplied from the above are converted into 5-bit encoding control signals CS, and each of the processing modules described above, that is, under color removal / black generation and data selection means 103, filter 105, and coloring processing means 106 are converted. , And γ conversion means 107. Normally, signals required for each processing module are supplied to each processing module from among the 10-bit control signals. However, in general, not all combinations (information) of 10-bit control signals are required. Therefore, the control signal encoding means 112 generates a 5-bit encoded control signal CS by taking out only a necessary combination (information) from combinations of 10-bit control signals. Therefore, it is only necessary for each processing module to extract only the information necessary for the processing module from the 5-bit encoding control signal CS. In other words, this corresponds to taking out a common control signal for all the processing modules. Next, the delay means 113-1, 113-2, and 113-3 indicate the timing of supplying the encoded control signal CS encoded by the control signal encoding means 112 to each processing module. Is synchronized with the timing at which the image processing is completed and output to the subsequent processing module. In the first embodiment, as will be described later, the processing time in each processing module (the time from when the image data is input until it is output) is unified, so that each delay means 113-1, 113-2, The same delay time is set in each of 113-3.
[0022]
B-2. Configuration of encoding control signal
Next, FIG. 3 is a schematic diagram showing a configuration example of the encoded control signal CS encoded by the control signal encoding means 112 described above. In FIG. 3, the encoding control signal CS is composed of 5-bit data. The fourth bit is a bit indicating whether or not there is coloring. The third bit is a bit indicating whether to output K color or other (Y, M, C). The second to 0th bits are used for selecting a coefficient in each processing module when coloring is not performed. In addition, when coloring is performed, the second to 0th bits are bits for selecting a multiplication coefficient in mono color. In the example shown in FIG. 3, no coloring, K color output, coefficient 105 plane of filter 105 (first coefficient), coefficient-2 plane of coloring processing means 106 (second coefficient), coefficient of γ conversion means 107 -1 plane (first coefficient).
[0023]
B-3. Configuration example of processing module
Next, FIG. 4 is a block diagram showing a schematic configuration of the processing module when the above-described filter 105 is taken as an example of the processing module. In FIG. 4, the filter 105 is realized by a partial function of an integrated circuit such as an LSI, and includes an image input unit 202, an image output unit 203, a filter body 204, and a decoding unit 205. The image input unit 202 and the image output unit 203 have a predetermined processing time until the image data supplied to the filter 105 is processed by the filter body 204 and output to the subsequent processing module (in this case, the coloring processing unit 106). It is a delay means for adjusting so that it may become. In the first embodiment, other processing modules, that is, under color removal / black generation and data selection means 103, coloring processing means 106, and γ conversion means 107 are also provided. The image input unit 202 and the image output unit 203 are for making the processing time (time from input of image data to output) in each processing module the same, and the delay time is the most processed. It is set according to the processing time of the slow processing module.
[0024]
As described above, the filter main body 204 is to perform the filter processing that is a function of the LSI, and includes four types of coefficients, that is, four surfaces as filter coefficients. As described above, the decoding unit 205 converts the encoding control signal CS encoded into 5 bits into a signal (2 bits) for selecting a coefficient (in this case, a filter coefficient), and outputs the signal to the filter body 204. Supply. The filter main body 204 performs filter processing on the image data based on the signal. Of course, the decoding unit 205 is also provided in other processing modules, that is, the under color removal / black generation and data selection means 103, the coloring processing means 106, and the γ conversion means 107. In each processing module, it goes without saying that the encoding control signal CS is converted into a signal for selecting individual coefficients corresponding to the module. As described above, each processing module includes the image input unit 202 and the image output unit 203, so that the difference in processing time due to the difference in the functions of the processing modules can be absorbed and the processing time can be unified to a predetermined time. It becomes. Further, since each processing module includes the decoding unit 205, the common encoding control signal CS can be decoded and converted into a signal that matches its own processing.
[0025]
C. Operation of Example 1
Next, the operation of the first embodiment will be described. First, when the reduction type line sensor of the image input unit 101 scans in the main scanning direction while moving in the sub-scanning direction at a speed corresponding to the enlargement / reduction magnification, the read B, G, R image data is read. Is converted into 8-bit digital image data by an A / D converter and supplied to the color space conversion means 102 and the area determination means 109. The color space conversion unit 102 improves the color, gradation, definition, other image quality, and reproducibility of the 8-bit digital image data of B, G, and R supplied from the image input unit 101. Various conversions and correction processes are performed, converted into toner primary colors Y, M, and C, and supplied to the under color removal / black generation and data selection means 103.
[0026]
On the other hand, in the area discriminating unit 109, the pixel is a character / color character / intermediate chroma character / picture area for each pixel based on the B, G, R signals read by the image input unit 101. It is discriminated whether or not it exists, and this discrimination result is supplied to the control signal encoding means 112 as a 2-bit discrimination signal. Further, when the operator instructs through the document type instruction unit 110 which image data is to be output in standard / character / photo / map type, this instruction signal is supplied to the control signal encoding unit 112. . Further, when the operator instructs the monochromatic, B / W, three-color, or four-color mode to output the image data via the monocolor designating means 111, the instruction signal is sent to the control signal. This is supplied to the encoding means 112.
[0027]
In the control signal encoding unit 112, the above-described area determination unit 109, document type instruction unit 110, andMonochromatic color designation means 111The total 10-bit control signal supplied from is converted into a 5-bit common encoding control signal CS and output. This encoding control signal CS is directly supplied to the under color removal / black generation and data selection means 103, and to the filter 105, coloring processing means 106, and γ conversion means 107, delay means 113-1 and 113, respectively. -2 and 113-3. First, in the under color removal / black generation and data selection means 103, the encoding control signal CS is converted into a signal for selecting a coefficient by a decoding unit (not shown). In the under color removal / black generation and data selection means 103, image data (Y, M, C signals) is delayed by an image input means (not shown), and then supplied to the under color removal / black generation means. The under color removal / black generation means performs under color removal and black generation on the Y, M, C signals converted by the color space conversion means 102 based on the signal. In the data selection means, the Y, M, C, and K signals that have undergone the above undercolor removal and black generation are sequentially selected and supplied to an image output means (not shown). In the image output means, the Y, M, C, and K signals are delayed and then output for each color.
[0028]
The Y, M, C, and K signals are sequentially supplied to the filter 105. In the filter 105, the Y, M, C, and K signals are delayed by the image input unit 202 and then supplied to the filter body 204. At the timing when the Y, M, C, and K signals are output from the under color removal / black generation and data selection means 103 to the filter 105, the encoding control signal CS is delayed from the delay means 113-1 and the filter 105 is output. Supplied to. In the filter 105, the encoding control signal CS is converted into a signal for selecting a coefficient by the decoding unit 205. Based on the signal, the filter main body 204 emphasizes edges in the case of characters and the like, and performs smoothing processing in the case of patterns and the like. When the processing in the filter main body 204 is completed, the image data is output after being delayed by the image output unit 203.
[0029]
The image data filtered by the filter 105 is supplied to the coloring processing means 106. In the coloring processing means 106, the filtered image data is delayed by an image input unit (not shown) and then supplied to the coloring processing body. The encoding control signal CS delayed by the delay unit 13-2 is supplied to the coloring processing unit 106 at a timing when the filtered image data is output to the coloring processing unit 106. In the coloring processing means 106, the encoding control signal CS is converted into a signal for selecting a coefficient by a decoding unit (not shown). In the coloring process main body, the image data is colored based on the signal. When the processing in the coloring process main body is completed, the image data is delayed and output by an image output unit (not shown).
[0030]
The image data subjected to the coloring process by the coloring process unit 106 is supplied to the γ conversion unit 107. In the γ conversion means 107, the image data subjected to the coloring process is delayed by an image input unit (not shown) and then supplied to the γ processing body. In addition, the encoding control signal CS delayed by the delay unit 13-3 is supplied to the γ conversion unit 107 at a timing when the image data subjected to the coloring process is output to the γ conversion unit 107. In the γ conversion means 107, the encoding control signal CS is converted into a signal for selecting a coefficient by a decoding unit (not shown). The γ conversion means 107 performs γ conversion according to the character mode, the picture mode, etc. based on the signal. When the process in the γ conversion main body is completed, the image data is delayed and output by an image output unit (not shown). This image data is printed on a predetermined sheet by the image output means 108.
[0031]
As described above, in the first embodiment, the control signal encoding unit 112 performs processing on each processing module (under color removal / black generation and data selection unit 103, filter 105, coloring processing unit 106, and γ conversion unit 107). In addition, by reducing the number of bits of the control signal indicating the processing contents, the decoding is performed so that each processing module is made common (encoded) and the common encoded control signal CS is decoded by each processing module. Since the unit is provided, it is not necessary to provide a means for generating a control signal for each processing module, and the circuit configuration can be simplified. Also, since one encoding control signal CS can be used in common for each processing module, the transmission path of the encoding control signal CS can be reduced. In addition, since the processing time of each processing module is made the same by providing the image input means and the image output means for delaying the input / output of the image data in each processing module, Processing can be performed even if the position is changed.
[0032]
D. Example 2
D-1. Block configuration of the second embodiment
FIG. 5 is a block diagram showing the configuration of the second embodiment of the present invention. It should be noted that parts corresponding to those in FIG. In the figure, in the second embodiment, instead of excluding the delay means 113-1 to 113-3 in the first embodiment, the configuration of each processing module is changed as will be described later. Therefore, each processing module is replaced with the undercolor removal / black generation and data selection means 103a, the filter 105a, the coloring processing means 106a, and the γ conversion means 107a instead of the reference numerals in FIG.
[0033]
D-2. Configuration example of processing module
Next, FIG. 6 is a block diagram showing a schematic configuration of a processing module when the above-described filter 105a is taken as an example. In the figure, the filter 105 a is realized by a part of the function of an integrated circuit such as an LSI, and includes a filter body 204, an input delay unit 402, an output delay unit 403, and a decoding unit 205. The input delay unit 402 and the output delay unit 403 delay the encoded control signal CS supplied from the control signal encoding unit 112. The input delay means 402 delays the encoding control signal CS supplied to the filter 105a for a predetermined time, and outputs delay means 403 andDecoding unit 205To supply. The output delay means 403 further delays the coding control signal delayed by the input delay means 402 and outputs the delayed signal to the subsequent processing module (in this case, the coloring processing means 106a). That is, the input delay unit 402 and the output delay unit 403 determine the timing at which the encoding control signal CS is output to the subsequent processing module (in this case, the coloring processing unit 106a) in the filter 105a that is the processing module. The processing ends after the image is supplied, and coincides with the timing of outputting the image data to the subsequent processing module. Therefore, the delay times of the input delay means 402 and the output delay means 403 are set according to the processing time required for the processing of each processing module (in this case, the filter 105a).
[0034]
In the above-described configuration, that is, the input delay unit 402, the output delay unit 403, and the decoding unit 205 are naturally other processing modules, that is, the under color removal / black generation and data selection unit 103a, the coloring processing unit 106a, and the like. It is also provided in the γ conversion means 107a. As described above, since each processing module includes the input delay means and the output delay means, the output timing to the subsequent stage of the encoding control signal CS can be adjusted according to the processing time due to the difference in the functions of the processing modules. It becomes. Further, since each processing module includes the decoding unit 205, the encoded encoding control signal CS can be shared.
[0035]
E. Operation of Example 2
Next, the operation of the above-described second embodiment will be described. First, when the reduction type line sensor of the image input unit 101 scans in the main scanning direction while moving in the sub-scanning direction at a speed corresponding to the reduction / enlargement magnification, the read B, G, R image data is read. Is converted into 8-bit digital image data by an A / D converter and supplied to the color space conversion means 102 and the area determination means 109. The color space conversion unit 102 improves the color, gradation, definition, other image quality, and reproducibility of the 8-bit digital image data of B, G, and R supplied from the image input unit 101. Various conversions and correction processes are performed, converted into toner primary colors Y, M, and C, and supplied to the under color removal / black generation and data selection means 103a.
[0036]
On the other hand, in the area discriminating unit 109, on the basis of the B, G, R signals read by the image input unit 101, for each pixel, the pixel is any of the character / color character / intermediate chroma character / pattern region. It is discriminated whether or not it exists, and this discrimination result is supplied to the control signal encoding means 112 as a 2-bit discrimination signal. Further, when the operator instructs through the document type instruction unit 110 which image data is to be output in standard / character / photo / map type, this instruction signal is supplied to the control signal encoding unit 112. . Further, when the operator instructs the monochromatic, B / W, three-color, or four-color mode to output the image data via the monocolor designating means 111, the instruction signal is sent to the control signal. This is supplied to the encoding means 112.
[0037]
In the control signal encoding unit 112, the above-described area determination unit 109, document type instruction unit 110, andMonochromatic color designation means 111The total 10-bit control signal supplied from is converted into a 5-bit encoded control signal CS and output. This encoding control signal CS is directly supplied to the under color removal / black generation and data selection means 103a. First, in the under color removal / black generation and data selection means 103a, the encoding control signal CS is delayed by an input delay means (not shown), then supplied to the decoding unit and converted into a signal for selecting a coefficient. In the under color removal / black generation means, under color removal and black generation are performed on the Y, M, and C signals which are converted by the color space conversion means 102 based on the above signals and directly supplied. In the data selection means, the Y, M, C, and K signals subjected to the above under color removal and black generation are sequentially selected and output for each color. At this time, the encoding control signal CS is output from output delay means (not shown) of the under color removal / black generation and data selection means 103a.
[0038]
The Y, M, C, K signals and the encoding control signal CS are directly supplied to the filter 105a. The encoding control signal CS is delayed by the input delay means 402 of the filter 105 a and then supplied to the decoding unit 205. In the filter 105 a, the encoding control signal CS is converted into a signal for selecting a coefficient by the decoding unit 205 and supplied to the filter body 204. Based on the signal, the filter main body 204 emphasizes edges in the case of characters and the like, and performs smoothing processing in the case of patterns and the like. When the processing in the filter body 204 is completed, the image data is directly supplied to the coloring processing means 106a. At this time,Filter 105aThe output delay means 403 outputs an encoding control signal CS.
[0039]
In the coloring processing unit 106a, the encoding control signal CS is delayed by an input delay unit (not shown) and then supplied to the decoding unit. In the coloring processing means 106a, the code control signal CS is converted into a signal for selecting a coefficient by the decoding unit and supplied to the coloring processing body. In the coloring process main body, the image data is colored based on the signal. Then, when the process in the coloring process main body is completed, the image data is directly supplied to the γ conversion means 107a. At this time, the encoding control signal CS is output from the output delay means of the coloring processing means 106a.
[0040]
In the γ conversion unit 107a, the encoding control signal CS is delayed by an input delay unit (not shown) and then supplied to the decoding unit. In the γ conversion means 107a, the code control signal CS is converted into a signal for selecting a coefficient by the decoding unit and supplied to the γ conversion main body. In the γ conversion main body, γ conversion corresponding to a character mode, a picture mode, and the like is performed based on the signal. When the process in the γ conversion main body is completed, the image data is directly supplied to the image output means 106a. This image data is printed on a predetermined sheet by the image output means 108.
[0041]
As described above, in the second embodiment, the control signal encoding unit 112 causes each processing module (under color removal / black generation and data selection unit 103a, filter 105a, coloring processing unit 106a, and γ conversion unit 107a) to be processed. A decoding unit for reducing the number of bits of the control signal instructing the processing contents to make common (encoding) to each processing module and decoding the common encoding control signal CS to each processing module Therefore, it is not necessary to provide a means for generating a control signal for each processing module, and the circuit configuration can be simplified. Also, since the encoding control signal CS can be used in common for each processing module that performs different processing, it is not necessary to supply a control signal for each processing module, and the transmission path of the encoding control signal CS can be reduced. it can. In addition, since each of the processing modules is provided with an input delay means and an output delay means, the encoding control signal CS is delayed and output in synchronization with the output timing of the image data. Accordingly, the processing can be performed even if the position of the processing module is changed, and no unnecessary adjustment (delay) time is required.
[0042]
【The invention's effect】
As described above, according to the present invention, the control signal representing the processing content is encoded, the encoded control signal is decoded, and the signal for controlling the processing in each processing module is generated.I made it. For this reason,In each processing moduleEven when a unique (different) process is performed, a common encoding control signal can be used. (1) Although each process module can perform a unique (different) process, (2 ) It is not necessary to provide a large number of signal lines for each processing module, and the hardware scale can be reduced.The advantageat the same timecan get.
[Brief description of the drawings]
FIG. 1 is a block diagram illustrating a configuration of an image processing apparatus according to an embodiment of the present invention.
FIG. 2 is a block diagram showing a configuration of Embodiment 1 of the present invention.
FIG. 3 is a schematic diagram illustrating a configuration example of an encoded control signal encoded by a control signal encoding unit according to the present exemplary embodiment.
FIG. 4 is a block diagram illustrating a schematic configuration of a processing module when the filter according to the first embodiment is taken as an example.
FIG. 5 is a block diagram showing a configuration of Embodiment 2 of the present invention.
FIG. 6 is a block diagram showing a schematic configuration of a processing module when the filter of the second embodiment is taken as an example.
FIG. 7 is a block diagram showing a schematic configuration of a conventional image processing apparatus.
[Explanation of symbols]
30 base machine
31 Platen glass
32 Image input terminal
33 Electrical control storage
34 Image output terminal
35 Paper tray
35a Paper transport path
35b SSI
35a Paper transport path
36 User interface
37 Imaging unit
38 wires
39 Drive pulley
40 Scanner
40a Laser output section
40b Polygon mirror
40c F / Θ lens
40d reflection mirror
41 Sensitive belt
41a Drive pulley
41b Cleaner 41
41c charger
41d Developer 41d
41e transfer device
42 Transfer device
43 Vacuum transfer device
45 Fixing device
51 color CRT display
52 Hard control panel
53 Infrared Touch Board
61 Edit Pad
62 Auto Document Feeder
63 Sorter
64 film projector
65 Mirror unit
101 Image input means
102 color space conversion means
103, 103a Under color removal / black generation and data selection means (image processing unit)
105, 105a Filter (image processing unit)
106, 106a Coloring processing means (image processing unit)
107, 107a γ conversion means (image processing unit)
108 Image output means
109 Area discrimination means
110 Document type instruction means
111 Monocolor color designation means
112 Control signal encoding means (control signal encoding unit)
113 -1 , 113 -2 , 113 -3 Delay means
202 Image input unit (delay means)
203 Image output unit (delay means)
204 Filter body (image processing means)
205 Decoding unit (decoding means)
CS encoding control signal (encoded signal)
402 Input delay means
403 Output delay means

Claims (2)

In an image processing apparatus including a plurality of image processing units that perform image processing on image data,
A control signal encoding unit that outputs a control signal representing the content of image processing performed on image data as an encoded signal common to the plurality of image processing units;
Each of the image processing units, decoding means for decoding the encoded signal supplied from the control signal encoding unit into a control signal according to the unique image processing,
An image processing apparatus comprising: an image processing unit that decodes the input image data by the decoding unit and performs image processing based on a control signal. The image processing unit includes a delay unit that adjusts a time required for image data from being supplied to the image processing unit to be output so that the processing time is the same for each of the plurality of image processing units. The image processing apparatus according to claim 1.

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