JP4855345B2 - Image processing apparatus and image forming apparatus - Google Patents

Description

  The present invention includes a scanner having two different reading units, an image processing apparatus that processes a monochrome image and a color image, a copy including the image processing apparatus, a FAX, and a digital that combines these functions. The present invention relates to an image forming apparatus such as a multifunction peripheral.

  As this type of technology, the inventions disclosed in Patent Documents 1 to 4 are known. Among these, in Patent Document 1, even when a plurality of pieces of image information are input as in the case of simultaneous reading of the front and back sides of a document, one connection port to the parallel bus used for transfer and one transfer destination reception channel are used. In addition, for the purpose of increasing the transfer speed, each reading unit simultaneously reads the front and back sides of the document, and each digitized image data is written at high speed with a toggle buffer of an I / F control unit with a data compression / decompression circuit. After passing through the buffer, it is stored in the primary memory MEM (1) by time-division writing, and then the front and back sides of the document are read sequentially, the scanner image processing is performed by the image processor, and the frame is transmitted via the parallel bus and the image memory controller. It is stored in the memory / HDD, and the read timing from the primary memory is a line counter signal that checks the input / output of the primary memory. Invention is disclosed for connection control.

  Further, Patent Document 2 aims to improve output productivity from a reading device in simultaneous duplex reading in which both images formed on the front and back sides of a document can be read as color images. The apparatus reads the images formed on the front and back surfaces of the document as color images by conveying the document once, and the surface image data read by the CCD image sensor and the back image data read by the CIS are in the sub-scanning direction. By halving the resolution, each data amount is reduced to half of the original data amount, and the front surface image data and the back surface image data in which the data amount is halved are originally provided to store one back surface image data. Stored in a separate memory, and then read the next document as a color image using a CCD image sensor and CIS. While taking, the invention transfers the surface image data and back image data before the document to be stored in the memory to the outside is disclosed.

  Patent Document 3 discloses a shading correction for the purpose of suppressing the occurrence of a difference in image quality in the read image data on the front and back surfaces in the simultaneous double-side reading capable of reading the images formed on both the front and back surfaces of the document. The characteristics unique to each reading unit determined by the relationship between the light source (illumination lamp or LED) and the sensor (by the CCD image sensor or CIS) are pre-processed in the dedicated front surface pre-processing unit and back surface pre-processing unit, respectively. For other general image quality-related filter processing, enlargement / reduction processing, color conversion processing, gradation conversion processing (TRC), or full surface AE and TI separation, both the front surface image data and the back surface image data are the same An invention for performing post-processing in the processing unit is disclosed.

Further, Patent Document 4 aims to reduce the size and cost of an apparatus that acquires shading data on the front and back sides in so-called double-sided simultaneous reading that can read images formed on both sides of a document. The image reading apparatus reads the image formed on the first surface of the document with the CCD image sensor and the image formed on the second surface of the document with the CIS substantially at the same time by conveying the document once. CCD shading data for shading correction of the image data of the first side of the document read by the CCD image sensor and CIS shading for correcting shading of the image data of the second side of the same document read by the CIS 50 An invention for creating data with the same shading data creation circuit is disclosed.
JP 2002-109527 A JP 2006-013882 A JP 2006-013924 A JP 2006-080941 A

  Many inventions are known in which both the front and back sides of a document are simultaneously read and predetermined image processing is performed on the read image data. In these inventions, when there are various image reading means, many of them are provided with dedicated hardware configurations. In addition, since color image data and monochrome image data require RGB three-color processing, there are many data transfer buses dedicated to color image data processing and monochrome image processing. . In this way, if each means is provided with a dedicated hardware configuration, it is easy to bring out features according to the image reading means, but on the other hand, separate devices are assembled, leading to an increase in design man-hours and circuit. It cannot be denied that the scale increases and the cost increases. Further, if the color image and the monochrome image are prepared, the cost further increases.

  Therefore, the problem to be solved by the present invention is to suppress the expansion of the circuit scale and process efficiently when processing image data read by two different image reading means.

In order to solve the above-mentioned problem, the first means receives the first and second reading means and the image data read by the first and second reading means, and various images are input to the image data. An image processing apparatus having a plurality of stages of image processing means for performing processing, wherein the image processing means performs common processing on the image data input from the first and second reading means, respectively. Then, the image data having different characteristics input from the first and second reading means are input to the subsequent stage after the first and second reading means and before the plurality of image processing means, respectively. of converting the image processing unit can be processed image data in a common processing arrangement, the image data receiving means for outputting, provided on one of said first and second reading means, those Signal processing means that performs image processing according to the characteristics of one reading means, and sets the image data of the other reading means to output image data from the image receiving means and image data having common characteristics that can be processed in the next stage When the first and second reading means are changed from color reading to monochrome reading, the image processor of the image data receiving means that receives and processes image data from the other reading means An image path from which the image data from the other reading unit is input and an image path from which the image data from the one reading unit is input are represented by RGB image paths. Two different image paths are set, and the one of the monochrome image data input to the two image paths. The image data input from the reading means is input to one of the image paths that accept the image data from the one reading means of the image processing means at the subsequent stage of the image data receiving means, and is input from the other reading means. The image data is inputted as it is to an image path that accepts image data from the other reading means of the image processing means in the subsequent stage .

Second means includes an image processing apparatus according to the first aspect, wherein the image forming apparatus and an image forming means for forming an image based on image data from the image processing apparatus.

  In the embodiment described later, the first reading unit is the first reading unit 1 and the SBU (CCD 1b) 1a and 1a ′, and the second reading unit is the second reading unit 2 and the CIS units 2a and 2a ′. , 2a ″, the multi-stage image processing means is the memory control section 4, the image processing section 6, the writing image processing section 7 and the VDC 8, the image data receiving means is the image data receiving section 3, and the signal processing means is the CCD correction process. Units 31, 31a, 3P1, CIS correction processing units 32, 32a, 32b, black pixel correction processing 33, shading correction processing 34, 36, background correction processing 35, 38, streak correction processing 37, and storage means in memory 5. The storage control unit corresponds to the memory control unit 4, and the image forming unit corresponds to the VDB 9.

According to the present invention, when processing the image data read by the different two image reading means, it is possible to suppress the enlargement of the circuit scale, processing efficiently.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings.

  FIG. 1 is a functional block diagram showing a schematic configuration of an image processing apparatus according to an embodiment of the present invention. In the figure, the image processing apparatus according to the present embodiment includes first and second reading units 1 and 2, an image data receiving unit 3, a memory control unit 4, an image processing unit 6, and writing along the flow of image signals. An image processing unit 7, a VDC 8, and a VDB 9 are provided, a memory 5 is connected to the memory control unit 4, and an image memory control unit 10 is connected to the image processing unit 5 via a bus 13. Further, a CPU 11 and a CPU memory 12 are provided, and are connected to the units 1 to 9 through the bus 14 so as to communicate with each other.

  The first and second reading units 1 and 2 optically scan the document to read an image on the document and generate image data as an electrical signal. The respective image data generated by the first and second reading units 1 and 2 are input to the image data receiving unit 3.

  The image data input unit 3 performs scanner processing based on the characteristics of the received image data. Specifically, images read by the first and second reading units 1 and 2 include processing such as shading correction for correcting variations in image density caused by distortion of the light amount distribution and adjusting the background density according to the background of the document. This is done for each data.

  The image data read by the first and second reading units 1 and 2 is input to the memory control unit 4 at the next stage. The memory control unit 4 stores the image data received from the first and second reading units 1 and 2 in the memory 5 for each frame. The image data stored in the memory 5 for each frame is extracted for each frame from the image data read by the first reading unit 1 and sent to the image processing unit 6 at the next stage. The image processing unit 6 performs various image processing and then sends the processed data to the image memory control unit 10 via the bus 13. Although not shown, the image memory control unit 10 has a storage for the purpose of handling a large amount of image data. Image data is stored in the storage, the next input image is received, or the image data stored for hard copy is sent to the image processing unit 6. As described above, the image memory control unit 10 has a function of controlling storage processing of image data and extraction of image data from the storage using the storage.

  In this embodiment, since the image data from the first reading unit 1 is processed first, the image data to be handled next is the image data from the second reading unit 2. The image data from the second reading unit 2 is processed in the same manner as the image data from the first reading unit 1, the data is taken out from the storage in response to a request, sent to the image processing unit 6, and the first reading unit 1. The same processing as the image data from The image processing unit 6 that has received the image data from the image memory control unit 10 sends the image data to the next-stage writing image processing unit 7.

  The writing image processing unit 7 performs image processing suitable for hard copy and sends image data to a VDC (Video Data Controller) 8 at the next stage. The VDC performs pre-processing such as changing the shape to an image format suitable for processing in the next-stage VDB (imaging unit) 9 and then sends the image data to the next-stage VDB 9. The VDB 9 performs writing processing on the received image data by laser diode light emission or other processing, and then transfers the image to recording paper by transfer processing to obtain a hard copy.

  Hereinafter, the configuration and operation of each unit of the image processing apparatus configured as described above will be further described.

  In the present embodiment, image data read from two different reading units 1 and 2 is received, and various types of image processing are performed. At that time, different signals are input by the two reading units 1 and 2, but the difference in the combination of these signals is absorbed by the image data receiving unit 3 so as to correspond to various image processing in the subsequent stages. ing.

  FIG. 2 is a functional block diagram showing the configuration of the first and second reading units 1 and 2 and the image data receiving unit 3. In the example of FIG. 2, the first reading unit 1 is composed of an SBU (sensor board unit) 1a, the second reading unit 2 is composed of a CIS (contact image sensor) unit 2a, and a CCD (charge coupled) is mounted on the SBU 1a. Device) 1b is mounted. On the other hand, the image data receiving unit 3 is provided with a CCD correction processing unit 31 and a CIS correction processing unit 32. The output from the SBU 1a is sent to the CCD correction processing unit 31, and the output from the CIS unit 2a is sent to the CIS correction processing unit 32. Entered.

  With this configuration, the image data read by the first reading unit 1 and the second reading unit 2 and converted into electric signals is input to the image data receiving unit 3. The image data receiving unit 3 that has received the image data from the SBU 1 a of the first reading unit 1 performs CCD correction processing by the CCD correction processing unit 31. The CCD correction processing unit 31 performs line processing according to the arrangement of the data of the CCD 1b, performs shading correction, and outputs to the next stage processing. Depending on the arrangement of the CCD 1b, for example, there is a structure in which an image is output in each channel of odd-numbered pixels and even-numbered pixels, or line data is halved and divided into first-half lines and second-half lines. In accordance with these various forms, a one-line process is performed to perform shading correction.

  The image data receiving unit 3 that has received the image data from the CIS unit 2 a of the second reading unit 2 performs CIS correction processing in the CIS correction processing unit 32. The CIS unit 2a is the same as that of the CCD 1b. Since there are various types of image output for the CIS unit 2a, the conversion process is performed according to each form, and the shading correction and the like are performed. Output after stage.

  The first and second reading units 1 and 2 that are the first stage of image data input are SBU 1a and CIS unit 2 in the configuration shown in FIG. 2, respectively, and the image data receiving unit 3 corresponds to this configuration by the CCD correction. A processing unit 31 and a CIS correction processing unit 32 are provided to process input image data from the SBU 1a and the CIS unit 2, respectively. However, the first and second reading units 1 and 2 are not limited to the configuration in FIG. 1, and various types can be adopted and changed. As described above, when the first and second reading units 1 and 2 are different in configuration, the data cut in the image data receiving unit 3 and the accompanying timing signal may have different specifications. In that case, it is necessary to cope with the changed specifications. However, when the entire configuration is recreated, not only costs are increased but also waste is increased. Accordingly, the change amount can be suppressed by switching to the image data receiving unit 3 corresponding to the reading units 1 and 2 so that the specification change can be dealt with.

  FIG. 3 is a block diagram showing this example. FIG. 3A shows a combination of the first and second reading units 1, 2 and the image data receiving unit 3 in FIG. 2, where the first reading unit 1 is the SBU 1 a and the second reading unit 2 is the same. In the CIS unit 2a, the image data receiving unit 3 is provided with a CCD correction processing unit 31 and a CIS correction processing unit 32. Read data from the CCD 1b of the SBU 1a is read into the CCD correction processing unit 31, and read data from the CIS unit 2a is read out. The information is input to the CIS correction processing unit 32.

  FIG. 3B shows an example in which the second reading unit 2 is also an SBU. In this example, the first reading unit 1 is configured by the first SBU 1a ′, and the second reading unit 2 is configured by the second SBU 1a ″. In this case, the image data receiving unit 3 is configured by the SBU 1a. It is necessary to correspond to the CCD 1b of “, 1a”. Therefore, when the combination of the reading units 1 and 2 in FIG. 3B is used, the image data receiving unit 3 is combined with the first and second CCD correction processing units 31a and 31b in accordance with the change. .

  FIG. 3C shows an example in which the first reading unit 1 is a CIS unit with respect to the configuration of FIG. In this example, the first reading unit 1 is configured by the first CIS unit 2a ′, and the second reading unit 2 is configured by the second CIS unit 2a ″. In this case, the image data receiving unit is configured. 3 must correspond to the CIS units 2a ′ and 2a ″. Therefore, when the combination of the reading units 1 and 2 in FIG. 3C is used, the image data receiving unit 3 is combined with the first and second CIS correction processing units 32a and 32b in accordance with the change. By handling in this way, it is possible to provide an image processing system by changing only the corresponding part without changing the overall configuration.

  In the example of FIG. 3, in order to perform processing according to the characteristics of the image data input from the reading units 1 and 2, the reading device used by the reading units 1 and 2 in the image data reception processing unit 3 is changed. Correspondingly, the functional elements of the reception processing unit 3 are changed and supported in hardware. However, instead of such a change of the correction processing unit, an image processor is used, and the difference in processing is determined by a program of the image processor. It can also be absorbed. FIG. 4 is a block diagram showing the configuration of the reception processing unit 3 corresponding to the change of the elements of the reading unit using such an image processing processor.

  FIG. 4A shows a functional configuration of the image processor 3P1 having processing functions of a black pixel correction process 33, a shading correction process 34, and a background correction process 35, and FIG. 2 shows a functional configuration of an image processing processor 3P2 having processing functions of a correction process 37 and a background correction process 38. Both the quantity image processing processors 3P1 and 3P2 are processed by the function for each color of RGB. As described with reference to FIG. 3, when the reading devices of the first and second reading units 1 and 2 are changed, the image processor 3P changes (switches) the processing function in response to the change. To do. This change is made on a program basis.

  For example, when the SBU (CCD) 1a is used for the first reading unit 1 and the CIS unit 2a is used for the second reading unit 2 as shown in FIG. 3A, for example, the image data receiving unit 3 uses FIG. The functional configuration shown in FIG. 4A is used for the first reading unit 1, and the functional configuration shown in FIG. 4B is used for the second reading unit 2. Then, in the configuration of FIG. 3B, both the first reading unit 1 and the second reading unit 2 use the functional configuration shown in FIG. Similarly, the functional configuration of FIG. 4B is used for both the first and second reading units 1 and 2 for the combination of FIG. By using the image processor in this way, it is possible to cope with various image reading means by changing the program.

  Here, the description has been made assuming a general image processing processor 3P, but the processing is implemented by a program for the processor so that a desired function operates when used. Then, it corresponds to each image.

  On the other hand, processing functions such as shading correction can be provided on the first and / or second reading units 1 and 2 side. In this case, for the processing function provided on the reading unit side, the processing on the image data receiving unit 3 side becomes unnecessary. Therefore, when the CIS correction processing function as shown in FIG. 4B is incorporated on the CIS unit 2a side, the processing function corresponding to the first reading unit 1 (SBU 1a) as shown in FIG. Here, only the CCD correction processing unit 31 is provided, and the CIS correction processing unit 32 as shown in FIG. 2 is not necessary. As a result, the image data from the second reading unit 2 passes through the image data receiving unit 3 and is output to the processing unit at the next stage.

  The configuration of FIG. 5 can be applied to a reading apparatus that supports monochrome images. That is, when the first and second reading units 1 and 2 in FIG. 5 are replaced with a monochrome reading device instead of a color reading device, the images from the two reading units 1 and 2 are improved by devising the image path. By using an image processor prepared for color image data for data input, each process can be performed by one image processor 3P.

  Therefore, assuming that the color input from the image reading units 1 and 2 shown in FIG. 5 is monochrome, the functions implemented in the image processor 3P used in the first reading unit 1 are as follows. Set for color. That is, the image processor 3P can receive frame data for three colors of RGB. For this reason, when both the first and second reading units 1 and 2 become monochrome specifications, the number of input frames is two, and the function is mounted by the image processor prepared for color. It will have a sufficient circuit scale. Therefore, in such a case, the processing function for two monochrome frames is implemented so that one image processor 3P can handle two-line input of monochrome image data.

  FIG. 6 is a block diagram illustrating a case where image data from the first reading unit 1 and the second reading unit 2 is input to the function unit for three frames. As can be seen from the figure, the processing stages 33, 34, and 35 in the image processor 3P sequentially process two frame data, and output the two frame data from the image processor 3P. The data to be output uses a color output path and uses an output portion for two colors.

  As shown in FIG. 6, when two monochrome input image data A are processed by one image processor 3P and output to the next stage, the output of the processed image data D is the memory control section which is the next stage processing section. It can be configured to accept two monochrome images from one input port for three colors. Reference numerals B, C, and D are monochrome image data processed by the processing stages 33, 34, and 35 of the image processor 3P.

  That is, out of the two output ports 3a and 3b (see FIG. 5) of the image data receiving unit 3, in the case of monochrome output, one output port (for example, 3a) is used, and 2 for color at the output port is further used. Output using the color paths 3a1 and 3b1 (see FIG. 6). Therefore, the image data is output to the memory control unit 4 at the next stage using one of the two inputs of the memory control unit 3 and further passing the image data using a path for two colors therein. .

  FIG. 7 shows a processing example of the image data receiving port of the memory control unit 4 in this case. FIG. 7 is an explanatory view showing details of the bus of the receiving port. In the example of FIG. 7, monochrome image data is input from the first reading unit 1 side to the R (red) path BUS-R (1) on the first reading unit 1 side, and the B (blue) bus BUS is input. Monochrome image data from the second reading unit 2 in monochrome is input to -B. In the memory control unit 4, the monochrome image data from the first reading unit 1 during monochrome of the R path BUS-R (1) is taken into the memory control unit 4 as it is.

  On the other hand, the image data from the second reading unit 2 in monochrome is input to the memory control unit 4 from the B bus BUS-B (1), branches from there, and the R path BUS on the second reading unit 2 side. -R (2) is taken up. Through this processing, a monochrome image can be received for both the first reading unit 1 side data and the second reading unit side data through processing by the image processing processor of the previous image data receiving unit 3P.

  The memory control unit 4 to which the image data is input uses the image data paths 3a1 and 3b1 of the first and second reading units 1 and 2 to handle color and monochrome images in the same way. That is, the address control and the data path control in the memory control unit 4 are functioned, and both the color data and the monochrome data are processed when the image data is stored in the memory 5.

  In the example of FIG. 7, the memory control unit 4 is processed using the R paths BUS-R (1) and (2) of the data buses 3a1 and 3a2, but in the subsequent processing (image processing unit 3) and subsequent processing. Outputs monochrome data using all RGB paths. That is, for the image data read from the memory 5, the R path data is output in parallel in the same way for both the G path and the B path on the respective buses 3a1 and 3a2. As described above, when monochrome image data is output from the memory control unit 4, a monochrome image is output to the color input port for the next stage image processing by matching the color image format using the RGB bus. be able to.

  By incorporating the monochrome image data into the RGB color path in this way, the monochrome image can be processed using the color image processing unit in the image processing after the memory control unit 4. This processing makes it possible to process image data without using a separate image path for monochrome. That is, by accepting monochrome image data in the same format from the input port of the color bus, it becomes possible to apply processing means common to color and monochrome for various image processing in the subsequent stages.

  As described above, according to the present embodiment, the following effects are obtained.

1) When the read image data is received and processed from the two different first and second reading units 1 and 2, the signals of the image data input from the respective reading units 1 and 2 with different combinations of signals Since the difference in the combination is absorbed by the image data receiving unit 3 and the same signal is obtained, various image processing in the subsequent stages can be handled with a common processing configuration.

2) By changing the processing function of the image data receiving unit 3, for example, the combination of the CCD correction processing unit 31 and the CIS correction processing unit 32, a combination of reading devices for inputting with a combination of different signals from another reading means. It can respond flexibly.

3) By configuring the image data receiving unit 3 with the image processor 3P, processing according to the characteristics of the image data from the first and second reading units 1 and 2 is performed based on the program of the image processor. As a result, the difference in the processing of the read data of the first and second reading units 1 and 2 can be absorbed by the program of the image processor 3P.

4) By providing the first and / or second reading units 1 and 2 with processing units for performing image processing for the reading units 1 and 2, the processing function in the image data receiving unit 3 is omitted, and the first The signals from the first and second reading units 1 and 2 can be made equivalent. As a result, various types of image processing in the subsequent stages can be handled with a common processing configuration.

5) For the first and second reading units 1 and 2, when using color reading as monochrome reading, by selecting an image path, image data can be input by the two reading units 1 and 2. On the other hand, the image data can be processed using one image processor prepared for color image data.

6) Two monochrome input image data can be output from one image processor to one input port for color by the next-stage processing unit, and can be subjected to image processing by the next-stage processing unit having a color processing function.

7) The memory control unit 4 stores image data in the memory 5 corresponding to each of the color image and the monochrome image. When the image data is extracted from the memory 5, the data is extracted according to the color image and the monochrome image. It can be transferred to the subsequent stage after processing is possible.

8) By matching the color image format when outputting monochrome image data from the memory control unit 4, the monochrome image data can be output to the color input port for the next stage image processing.

9) By accepting monochrome image data in the same format from the color input port, it is possible to apply color and monochrome processing means to various image processing in the subsequent stages.

1 is a functional block diagram illustrating a schematic configuration of an image processing apparatus according to an embodiment of the present invention. It is a functional block diagram which shows the structure of a 1st and 2nd reading part and an image data receiving part. It is a block diagram which shows various structures when an image data receiving part is switched. It is a block diagram which shows the example which comprised the image data receiving part with the image processor. It is a block diagram which shows the structure of the image data receiving part when the processing function is provided in the reading part side. It is a block diagram which shows the flow of image data when the image data from the 1st and 2nd reading part is input into the function part for 3 frames. It is explanatory drawing which shows the process example of the receiving port of the image data of a memory control part.

Explanation of symbols

1 1st reading part 1a SBU
1b CCD
2 Second reading unit 2a CIS unit 3 Image data receiving unit 3P Image processor 4 Memory control unit 5 Memory 6 Image processing unit 7 Write image processing unit 8 VDC
9 VDB
10 Image memory control

Claims (6)

First and second reading means;
A plurality of stages of image processing means for inputting image data read by the first and second reading means and performing various image processing on the image data;
In an image processing apparatus having
The image processing means is an image processing means for applying a common process to the image data input from the first and second reading means,
Image data having different characteristics input from the first and second reading means are processed in the subsequent stage after the first and second reading means and before the plurality of stages of image processing means, respectively. Image data receiving means for converting and outputting image data that can be processed with a common processing configuration in the means ;
Provided in one of the first and second reading means, executes image processing according to the characteristics of the one reading means, and outputs the image data of the other reading means from the output image data from the image receiving means and the next Signal processing means for making image data of common characteristics that can be processed in stages;
With
When the first and second reading means are changed from color reading to monochrome reading, an image processor of an image data receiving means for receiving and processing image data from the other reading means is supplied from the one reading means. Enter the image data,
An image path to which image data from the other reading unit is input and an image path to which image data from the one reading unit is input are set to two different image paths of RGB image paths,
The image data input from the one reading unit among the monochrome image data input to the two image paths is received as the image data from the one reading unit of the image processing unit following the image data receiving unit. Enter one of the image paths,
The image processing apparatus according to claim 1, wherein the image data input from the other reading unit is input as it is to an image path that accepts image data from the other reading unit of the subsequent image processing unit. The image processing apparatus according to claim 1.
The image data receiving means includes signal processing means for performing signal processing in accordance with characteristics of signals from the first and second reading means;
An image processing apparatus, wherein a combination of the signal processing means is changed according to a type of the signal. The image processing apparatus according to claim 2.
The image data receiving means comprises an image processor;
An image processing apparatus, wherein the signal processing means comprises a program. The image processing apparatus according to any one of claims 1 to 3 ,
Storage control means for storing the image data input from the image data receiving unit in the storage means at the subsequent stage of the image data receiving means and outputting the image data stored in the storage means to the image processing means in the subsequent stage. ,
The storage control means accumulates color image data and monochrome image data in the storage means,
When outputting monochrome image data from the storage control means, the storage control means outputs monochrome image data to the color image data input port of the next stage image processing means in accordance with the color image format. Processing equipment. The image processing apparatus according to claim 4.
The next-stage image processing means accepts the monochrome image data from the color image data input port in the same format, and applies processing means common to color and monochrome for various image processes in the subsequent stages. An image processing apparatus. An image processing apparatus according to any one of claims 1 to 5,
Image forming means for forming an image based on image data from the image processing device;
An image forming apparatus characterized by comprising a.

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