JP3877467B2 - Image processing device - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention performs image processing on digital image data, and more specifically, performs image processing, particularly density conversion processing, on digital image data in a digital multi-function peripheral having functions such as a copying machine, a facsimile, a printer, and a scanner. Image processing device It is about.
[0002]
[Prior art]
Conventionally, digital copiers that process image data digitized from analog copiers have appeared. Furthermore, in addition to the functions of copiers, digital copiers function not only as copiers, but also facsimile functions, There are digital multifunction peripherals that combine functions such as printer functions and scanner functions.
[0003]
FIG. 31 is a block diagram showing a hardware configuration of a digital multifunction peripheral according to the prior art.
[0004]
As shown in FIG. 31, the digital multi-function peripheral includes a series of components including a digital reading unit 3101, an image processing unit 3102, a video control unit 3103, and a writing unit 3104, and a memory control unit 3105 and a memory module 3106. By connecting a part (copier part) constituting the copier to be formed and a unit such as a facsimile control unit 3112, a printer control unit 3113, a scanner control unit 3114, etc. via a mother board 3111, digital Each function as a multifunction machine was realized.
[0005]
Accordingly, in the copier portion that realizes the function as a copier, each component of the reading unit 3101, the image processing unit 3102, the video control unit 3103, and the writing unit 3104 is configured by the system controller 3107, RAM 3108, and ROM 3109. While the series of operations of the copying machine is controlled, each unit such as the facsimile control unit 3112, the printer control unit 3113, and the scanner control unit 3114 uses a part of the established series of operations in the copying machine. As a result, the function of each unit was realized.
[0006]
In other words, the functions of the digital multi-function peripheral are realized by adding on the facsimile control unit 3112, the printer control unit 3113, and the scanner control unit 3114 to the copier portion established as one system by the series of components described above. Met. This is due to the fact that the above-described series of constituent parts are configured by hardware such as ASIC (Application Specific Integrated Circuit), thereby placing importance on processing speed (to increase the processing speed).
[0007]
Also disclosed is an “image processing apparatus” (for example, Japanese Patent Laid-Open No. 8-274986) that optimizes image processing of read signals, image storage in a memory, parallel operation of a plurality of functions, and respective image processing. Some image processing can be executed with a single image processing configuration.
[0008]
[Problems to be solved by the invention]
However, in the digital multi-functional peripheral in the above prior art, since the copying machine part is established as one system as described above, the copying machine part such as the facsimile control unit 2212, the printer control unit 2213, the scanner control unit 2214, etc. As for the units connected to, there is a problem that a system must be constructed independently of the copying machine part in order to realize each function.
[0009]
Therefore, when the density conversion of image data is performed, it is performed in a predetermined unit, and the density conversion procedure is also fixed. For this reason, there has been a problem that unnecessary density conversion may be performed as the image processing becomes multi-functional, which may cause image deterioration.
[0010]
In addition, when density conversion is not performed when necessary, the transfer amount of image data between units increases or the processing amount of image data increases, resulting in a decrease in image processing efficiency. There was a problem of letting it. Furthermore, there has been a problem that an excessive amount of memory is consumed due to an inadequate density conversion.
[0011]
The present invention eliminates the problems caused by the prior art described above, so that the density conversion process can be controlled optimally for the entire system. Image processing device The purpose is to provide.
[0012]
[Means for Solving the Problems]
In order to solve the above-described problems and achieve the object, an image processing apparatus according to the invention of claim 1 is provided: An image processing apparatus comprising an image processing means, an image data control means, and a selection means, wherein the image processing means For image data Edit processing And a first density conversion means for converting the density of the image data in the main scanning direction, and a second density conversion means for converting the density of the image data in the sub-scanning direction. The image data control means First image data read by image reading means for reading image data , Second image data read by image memory control means for controlling image memory to write / read image data , Third image data subjected to image processing by the image processing means , At least one of the image data Receive Received image data The image memory control means , The image processing means , Transfer image data on paper Image writing means for writing Either And send to Received image data A third density converting means for converting the density in the main scanning direction and a fourth density converting means for converting the density in the sub scanning direction of the received image data. The selection means includes: For each image data, a density conversion means for converting the density of each image data is selected from the first to fourth density conversion means. And Only the density converting means selected by the selecting means converts the density of each image data.
[0013]
According to the first aspect of the present invention, it is possible to freely set the order in which the density conversion processing is performed, thereby preventing the deterioration of the image, the data transfer amount between the units, the data processing amount ( Processing load) and the storage capacity of the image memory can be reduced.
[0014]
An image processing apparatus according to a second aspect of the present invention is the image processing apparatus according to the first aspect, wherein the image processing means applies the first image data read by the image reading means. Edit processing At least one of the first image processing means for applying the first image processing means and the first to third image data transmitted to the image writing means Edit processing And second image processing means for performing the processing.
[0015]
According to the second aspect of the present invention, optimal image processing can be performed by separately performing input image processing and output image processing on image data.
[0016]
An image processing apparatus according to a third aspect of the present invention is the image processing apparatus according to the first or second aspect, wherein the selection unit is arranged in the main scanning direction of the first image data read by the image reading unit. The density is converted by the third density conversion unit, and the density in the sub-scanning direction of the first image data read by the image reading unit is selected so that the fourth density conversion unit converts the density. And
[0017]
According to the invention described in claim 3, by performing image processing on the image after density conversion, it is possible to perform optimum input / output image processing on the image data after density conversion, The image data after density conversion can be provided to the image memory control means.
[0018]
An image processing apparatus according to a fourth aspect of the present invention is the image processing apparatus according to the first or second aspect of the present invention, wherein the selecting means transmits the third image data transmitted to the image writing means in the main scanning direction. The density is converted by the third density conversion unit, and the density in the sub-scanning direction of the third image data to be transmitted to the image writing unit is selected so as to be converted by the fourth density conversion unit. And
[0019]
According to the fourth aspect of the present invention, when density conversion is performed such that the amount of image data increases, the processing load on the image processing means can be reduced, and the image memory controlled by the image memory control means can be reduced. The storage capacity can be reduced, and the amount of data transferred between the image processing means and the image data control means can be reduced.
[0020]
An image processing apparatus according to a fifth aspect of the present invention is the image processing apparatus according to the first or second aspect, wherein the density in the main scanning direction of the second image data transmitted from the selection unit to the image processing unit is provided. Is converted by the third density conversion means, and the density in the sub-scanning direction of the second image data to be transmitted to the image processing means is selected to be converted by the fourth density conversion means. .
[0021]
According to the fifth aspect of the present invention, by performing output image processing on an image after density conversion, it is possible to perform optimum image processing on the image data after density conversion. When density conversion is performed so that the amount of data increases, the storage capacity of the image memory controlled by the image memory control means can be reduced.
[0022]
According to a sixth aspect of the present invention, in the image processing apparatus according to the first or second aspect of the present invention, the density in the main scanning direction of the second image data transmitted from the selection means to the image processing means. Alternatively, either the density in the sub-scanning direction is converted by the third density converting unit or the fourth density converting unit, and the density in the main scanning direction or the density in the sub-scanning direction of the second image data is converted. The density in the scanning direction that has not been subjected to density conversion is selected so that the first density conversion means or the second density conversion means converts the density.
[0023]
According to the sixth aspect of the present invention, the processing amount of both the image data control means and the image processing means can be reduced, and the output image processing is performed on the density-converted image, thereby obtaining the density. Optimum image processing can be performed on the converted image data, and the storage capacity of the image memory controlled by the image memory control means is reduced when density conversion is performed to increase the amount of image data. be able to.
[0024]
An image processing apparatus according to a seventh aspect of the present invention is the image processing apparatus according to the first or second aspect, wherein the selection unit is arranged in the main scanning direction of the first image data read by the image reading unit. Either the third density conversion means or the fourth density conversion means converts either the density or the density in the sub-scanning direction, First image data Of the densities in the main scanning direction or in the sub-scanning direction, the density in the scanning direction that has not been subjected to density conversion is selected so that the first density converting means or the second density converting means converts it. .
[0025]
According to the seventh aspect of the present invention, it is possible to reduce the processing amounts of both the image data control unit and the image processing unit, and to perform density conversion by performing image processing on the image after density conversion. Optimal input / output image processing can be performed on the subsequent image data, and the image data after density conversion can be provided to the image memory control means.
[0026]
According to an eighth aspect of the present invention, in the image processing apparatus according to the first to seventh aspects of the present invention, the image data control information further includes information relating to processing contents for the first to third image data. Image data information acquisition means for acquiring the image data, and the selection means selects the density conversion means based on the image data control information acquired by the image data information acquisition means.
[0027]
According to the eighth aspect of the present invention, the operator can freely set and change the density conversion procedure.
[0028]
DETAILED DESCRIPTION OF THE INVENTION
Exemplary embodiments of an image processing apparatus according to the present invention will be explained below in detail with reference to the accompanying drawings.
[0029]
First, the principle of the image processing apparatus according to this embodiment will be described. FIG. 1 is a block diagram functionally showing the configuration of the image processing apparatus according to this embodiment of the present invention. In FIG. 1, the image processing apparatus includes the following five units.
[0030]
The five units are an image data control unit 100, an image reading unit 101 for reading image data, an image memory control unit 102 for controlling image memory for storing images and writing / reading image data, and an image. An image processing unit 103 that performs image processing such as processing editing on the data, and an image writing unit 104 that writes the image data on transfer paper or the like.
[0031]
Each of the above units has an image reading unit 101, an image memory control unit 102, an image processing unit 103, and an image writing unit 104 connected to the image data control unit 100, with the image data control unit 100 as the center. Yes.
[0032]
(Image data control unit 100)
The processes performed by the image data control unit 100 include the following. For example,
[0033]
(1) Data compression processing (primary compression) for improving data bus transfer efficiency, (2) Transfer processing of primary compressed data to image data,
(3) Image composition processing (image data from a plurality of units can be synthesized. In addition, synthesis on a data bus is also included),
(4) Image shift processing (image shift in the main scanning and sub-scanning directions),
(5) Image area expansion processing (the image area can be enlarged to the periphery by an arbitrary amount), (6) Image scaling processing (for example, 50% or 200% fixed scaling),
(7) Parallel bus interface processing,
(8) Serial bus interface processing (interface with process controller 211 described later),
(9) Parallel data and serial data format conversion processing,
(10) Interface processing with the image reading unit 101,
(11) Interface processing with the image processing unit 103,
Etc.
[0034]
(Image reading unit 101)
The processes performed by the image reading unit 101 include the following. For example,
[0035]
(1) Document reflected light reading process by optical system,
(2) Conversion processing into an electric signal in a CCD (Charge Coupled Device).
(3) Digitization processing by A / D converter,
(4) Shading correction processing (processing for correcting illuminance distribution unevenness of the light source),
(5) Scanner γ correction processing (processing for correcting the density characteristics of the reading process)
Etc.
[0036]
(Image memory control unit 102)
The processing performed by the image memory control unit 102 includes the following. For example,
[0037]
(1) Interface control processing with the system controller,
(2) Parallel bus control processing (interface control processing with parallel bus),
(3) Network control processing,
(4) Serial bus control processing (control processing of multiple external serial ports),
(5) Internal bus interface control processing (command control processing with the operation unit),
(6) Local bus control processing (ROM, RAM, font data access control processing for starting the system controller),
(7) Memory module operation control processing (memory module write / read control processing, etc.)
(8) Memory module access control processing (processing to arbitrate memory access requests from multiple units),
(9) Data compression / decompression processing (processing to reduce the amount of data for effective use of memory),
(10) Image editing processing (memory area data clear, image data rotation processing, image composition processing in memory, etc.),
Etc.
[0038]
(Image processing unit 103)
The processing performed by the image processing unit 103 includes the following. For example,
[0039]
(1) Shading correction processing (processing for correcting illuminance distribution unevenness of the light source),
(2) Scanner γ correction processing (processing for correcting the density characteristics of the reading process),
(3) MTF correction processing,
(4) Smoothing process
(5) Arbitrary scaling processing in the main scanning direction,
(6) Density conversion (γ conversion processing: corresponding to density notch),
(7) Simple multi-value processing
(8) Simple binarization processing,
(9) error diffusion processing,
(10) Dither processing,
(11) Dot arrangement phase control processing (right dot, left dot),
(12) Isolated point removal processing,
(13) Image area separation processing (color determination, attribute determination, adaptive processing),
(14) Density conversion processing,
Etc.
[0040]
(Image writing unit 104)
The processes performed by the image writing unit 104 include the following. For example,
[0041]
(1) Edge smoothing process (jaggy correction process),
(2) Correction processing for dot rearrangement,
(3) Image signal pulse control processing,
(4) Parallel data and serial data format conversion processing,
Etc.
[0042]
(Hardware configuration of digital multifunction device)
Next, a hardware configuration when the image processing apparatus according to the present embodiment constitutes a digital multi-function peripheral will be described. FIG. 2 is a block diagram showing an example of a hardware configuration of the image processing apparatus according to the present embodiment.
[0043]
In the block diagram of FIG. 2, the image processing apparatus according to the present embodiment includes a reading unit 201, a sensor board unit 202, an image data control unit 203, an image processing processor 204, and a video data control unit 205. And an image forming unit (engine) 206. The image processing apparatus according to the present embodiment includes a process controller 211, a RAM 212, and a ROM 213 via a serial bus 210.
[0044]
Also, the image processing apparatus according to the present embodiment includes an image memory access control unit 221, a memory module 222, a facsimile control unit 224, and an image memory access control unit 221 via the parallel bus 220. A system controller 231, a RAM 232, a ROM 233, and an operation panel 234.
[0045]
Here, the relationship between each component described above and each unit 100 to 104 shown in FIG. 1 will be described. That is, the function of the image reading unit 101 shown in FIG. 1 is realized by the reading unit 201 and the sensor board unit 202. Similarly, the function of the image data control unit 100 is realized by the image data control unit 203. Similarly, the function of the image processing unit 103 is realized by the image processor 204.
[0046]
Similarly, the image writing unit 104 is realized by the video / data control unit 205 and the image forming unit (engine) 206. Similarly, an image memory control unit is realized by the image memory access control unit 221 and the memory module 222.
[0047]
Next, the contents of each component will be described. A reading unit 201 that optically reads a document includes a lamp, a mirror, and a lens, and condenses reflected light of lamp irradiation on the document on a light receiving element by the mirror and the lens.
[0048]
A light receiving element, for example, a CCD is mounted on the sensor board unit 202, and image data converted into an electrical signal in the CCD is converted into a digital signal and then output (transmitted) from the sensor board unit 202.
[0049]
Image data output (transmitted) from the sensor board unit 202 is input (received) to the image data control unit 203. The image data control unit 203 controls all image data transmission between the functional device (processing unit) and the data bus.
[0050]
The image data control unit 203 is a system controller that controls the image board with respect to the image data, the sensor board unit 202, the parallel bus 220, the data transfer between the image processing processors 204, and the process controller 211 for the image data and the overall control of the image processing apparatus. Communication with 207 is performed. The RAM 212 is used as a work area for the process controller 211, and the ROM 213 stores a boot program for the process controller 211 and the like.
[0051]
The image data output (transmitted) from the sensor board unit 202 is transferred (transmitted) to the image processing processor 204 via the image data control unit 203, and signal degradation (quantization into an optical system and a digital signal) The signal deterioration of the scanner system) is corrected and output (transmitted) to the image data control unit 203 again.
[0052]
The image memory access control unit 221 controls writing / reading of image data to / from the memory module. It also controls the operation of each component connected to the system / parallel bus 220. The RAM 232 is used as a work area for the system controller 231, and the ROM 233 stores a boot program for the system controller 231.
[0053]
The operation panel 234 inputs processing to be performed by the image processing apparatus. For example, the type of processing (copying, facsimile transmission, image reading, printing, etc.), the number of processings, etc. are input. Thereby, the image data control information can be input. The contents of the facsimile control unit 224 will be described later.
[0054]
Next, there are a job in which the read image data is stored in the memory module 222 and reused, and a job in which the read image data is not stored in the memory module 222. Each case will be described. As an example of storing in the memory module 222, when a plurality of copies of one document are copied, the reading unit 201 is operated only once and image data read by the reading unit 201 is stored in the memory module 222. There is a method of reading accumulated image data a plurality of times.
[0055]
As an example of not using the memory module 222, when only one original is copied, the read image data may be reproduced as it is, so that the image memory access control unit 221 can access the memory module 222. There is no need to do it.
[0056]
First, when the memory module 222 is not used, the data transferred from the image processor 204 to the image data controller 203 is returned from the image data controller 203 to the image processor 204 again. The image processor 204 performs image quality processing for converting luminance data by the CCD in the sensor board unit 202 into area gradation.
[0057]
The image data after the image quality processing is transferred from the image processor 204 to the video data control unit 205. The post-processing relating to dot arrangement and pulse control for reproducing the dots are performed on the signal changed to the area gradation, and then a reproduced image is formed on the transfer paper in the image forming unit 206.
[0058]
Next, a description will be given of the flow of image data in the case where additional processing such as rotation of the image direction, image synthesis, and the like is performed at the time of reading the image stored in the memory module 222. The image data transferred from the image processor 204 to the image data control unit 203 is sent from the image data control unit 203 to the image memory / access control unit 221 via the parallel bus 220.
[0059]
Here, based on the control of the system controller 231, image data and access control of the memory module 222, development of print data of an external PC (personal computer) 223, and image data for effective use of the memory module 222 Compress / decompress
[0060]
The image data sent to the image memory access control unit 221 is accumulated in the memory module 222 after data compression, and the accumulated image data is read out as necessary. The read image data is decompressed, restored to the original image data, and returned from the image memory / access control unit 221 to the image data control unit 203 via the parallel bus 220.
[0061]
After transfer from the image data control unit 203 to the image processing processor 204, image quality processing and pulse control by the video data control unit 205 are performed, and a reconstructed image is formed on the transfer paper in the image forming unit 206.
[0062]
In the flow of image data, the functions of the digital multi-function peripheral are realized by the bus control in the parallel bus 220 and the image data control unit 203. In the facsimile transmission function, the read image data is subjected to image processing by the image processor 204 and transferred to the facsimile control unit 224 via the image data control unit 203 and the parallel bus 220. The facsimile control unit 224 performs data conversion to the communication network and transmits the data to the public line (PN) 225 as facsimile data.
[0063]
On the other hand, the received facsimile data is converted from line data from the public line (PN) 225 to image data by the facsimile control unit 224, and to the image processor 204 via the parallel bus 220 and the image data control unit 203. Transferred. In this case, no special image quality processing is performed, the video / data control unit 205 performs dot rearrangement and pulse control, and the image forming unit 206 forms a reproduced image on the transfer paper.
[0064]
In a situation where a plurality of jobs, for example, a copy function, a facsimile transmission / reception function, and a printer output function operate in parallel, the system controller 231 and the process allocate the right to use the reading unit 201, the image forming unit 206, and the parallel bus 220 to the job. Control is performed by the controller 211.
[0065]
The process controller 211 controls the flow of image data, and the system controller 231 controls the entire system and manages the activation of each resource. The function selection of the digital multi-function peripheral is selected and input on the operation panel (operation unit) 234, and processing contents such as a copy function and a facsimile function are set.
[0066]
The system controller 231 and the process controller 211 communicate with each other via the parallel bus 220, the image data control unit 203, and the serial bus 210. Specifically, communication between the system controller 231 and the process controller 211 is performed by performing data format conversion for the data interface between the parallel bus 220 and the serial bus 210 in the image data control unit 203.
[0067]
(Image processing unit 103 / image processing processor 204)
Next, an outline of processing in the image processing processor 204 constituting the image processing unit 103 will be described. FIG. 3 is a block diagram showing an outline of processing of the image processing processor 204 of the image processing apparatus according to the present embodiment.
[0068]
In the block diagram of FIG. 3, the image processing processor 204 includes a first input I / F 301, a scanner image processing unit 302, a first output I / F 303, a second input I / F 304, and an output image processing unit 305. The second output I / F 306 is included.
[0069]
In the above configuration, the read image data is transmitted from the first input interface (I / F) 301 of the image processor 204 to the scanner image processor 302 via the sensor board unit 202 and the image data controller 203. .
[0070]
The purpose of the image processing here is to correct the deterioration of the read image data. Specifically, shading correction, scanner γ correction, MTF correction, and the like are performed. Although not correction processing, enlargement / reduction scaling processing can also be performed. When the correction processing of the read image data is completed, the image data is transferred to the image data control unit 203 via the first output interface (I / F) 303. The above processing is first image processing (input image processing) described later.
[0071]
When outputting to transfer paper, the image data from the image data control unit 203 is received from the second input I / F 304 and the image quality processing unit 305 performs area gradation processing. The image data after the image quality processing is output to the video data control unit 205 or the image data control unit 203 via the second output I / F 306. The above processing is second image processing (output image processing) described later.
[0072]
Area gradation processing in the image quality processing unit 305 includes density conversion processing, dither processing, error diffusion processing, and the like, and mainly performs area approximation of gradation information. Once the image data processed by the scanner image processing unit 302 is stored in the memory module 222, various reproduced images can be confirmed by changing the image quality processing by the image quality processing unit 305.
[0073]
For example, the atmosphere of the reproduced image can be easily changed by changing (changing) the density of the reproduced image or by changing the number of lines of the dither matrix. At this time, it is not necessary to read the image again from the reading unit 201 every time the processing is changed, and the image data accumulated from the memory module 222 is read, so that different processing can be performed on the same image data any number of times. Can be implemented quickly.
[0074]
In the case of a single scanner, scanner image processing and gradation processing are performed together and output to the image data control unit 203. The processing content can be changed in a programmable manner. Processing switching, processing procedure changes, and the like are managed by the command control unit 307 via the serial I / F 308.
[0075]
Next, the internal configuration of the image processor 204 will be described. FIG. 4 is a block diagram showing an internal configuration of the image processing processor 204 of the image processing apparatus according to this embodiment. In the block diagram of FIG. 4, a plurality of input / output ports 401 are provided for data input / output with the outside, and data input and output can be arbitrarily set respectively.
[0076]
In addition, a bus switch / local memory group 402 is provided inside so as to be connected to the input / output port 401, and the memory control unit 403 controls the memory area to be used and the path of the data path. The input data and the data for output are assigned to the bus switch / local memory group 402 as a buffer memory, stored in each, and the external I / F is controlled.
[0077]
Various processing is performed in the processor array unit 404 on the image data stored in the bus switch / local memory group 402, and the output result (processed image data) is again sent to the bus switch / local memory group 402. Store. The processing procedure of the processor, parameters for processing, and the like are exchanged between the program RAM 405 and the data RAM 406.
[0078]
The contents of the program RAM 405 and data RAN 406 are downloaded from the process controller 211 to the host buffer 407 via the serial I / F 408. Further, the process controller 211 reads the contents of the data RAM 406 and monitors the progress of processing.
[0079]
If the processing contents are changed or the processing form required by the system is changed, the contents of the program RAM 405 and the data RAM 406 referred to by the processor array unit 404 are updated.
[0080]
(Image Data Control Unit 100 / Image Data Control Unit 203)
Next, an outline of processing in the image data control unit 203 constituting the image data control unit 100 will be described. FIG. 5 is a block diagram showing an outline of processing of the image data control unit 203 of the image processing apparatus according to the present embodiment.
[0081]
In the block diagram of FIG. 5, the image data input / output unit 501 inputs (receives) image data from the sensor board unit 202 and outputs (transmits) image data to the image processing processor 204. In other words, the image data input / output unit 501 is a component for connecting the reading unit 101 and the image processing unit 103 (image processing processor 204), and transmits image data read by the reading unit 101 to the image processing unit 103. It can be said that this is a dedicated input / output unit only for this purpose.
[0082]
The image data input control unit 502 inputs (receives) the image data that has been subjected to the scanner image correction by the image processing processor 204. The input image data is subjected to data compression processing in the data compression unit 503 in order to increase the transfer efficiency in the parallel bus 220. Thereafter, the data is sent to the parallel bus 220 via the data converter 504 and the parallel data I / F 505.
[0083]
Since the image data input from the parallel bus 220 via the parallel data I / F 505 is compressed for bus transfer, it is sent to the data decompression unit 506 via the data conversion unit 504, where the data Perform decompression processing. The expanded image data is transferred to the image processor 204 in the image data output control unit 507.
[0084]
The image data control unit 203 also has a conversion function between parallel data and serial data. The system controller 231 transfers data to the parallel bus 220, and the process controller 211 transfers data to the serial bus 210. The image data control unit 203 performs data conversion for communication between the two controllers.
[0085]
The serial data I / F includes a first serial data I / F 507 that exchanges data with the process controller via the serial bus 210, and a second serial data I that is used to exchange data with the image processor 204. / F508 is provided. By having one system independently with the image processor 204, the interface with the image processor 204 can be smoothed.
[0086]
The command control unit 509 controls the operation of each component unit and each interface in the image data control unit 203 described above in accordance with the input command.
[0087]
(Image writing unit 104 / video data control unit 205)
Next, an outline of processing in the video / data control unit 205 constituting a part of the image writing unit 104 will be described. FIG. 6 is a block diagram showing an outline of processing of the video / data control unit 205 of the image processing apparatus according to the present embodiment.
[0088]
In the block diagram of FIG. 6, the video data control unit 205 performs additional processing on input image data according to the characteristics of the image forming unit 206. That is, the edge smoothing processing unit 601 performs dot rearrangement processing by edge smoothing processing, the pulse control unit 602 performs pulse control of the image signal for dot formation, and forms the image data subjected to the above processing. Output to unit 206.
[0089]
In addition to the conversion of image data, a format conversion function for parallel data and serial data is provided, and the video data control unit 205 alone can support communication between the system controller 231 and the process controller 211. That is, a parallel data I / F 603 that transmits / receives parallel data, a serial data I / F 604 that transmits / receives serial data, and a data converter that mutually converts data received by the parallel data I / F 603 and the serial data I / F 604 605, the format of both data is converted.
[0090]
(Image Memory Control Unit 102 / Image Memory Access Control Unit 221)
Next, an outline of processing in the image memory / access control unit 221 constituting a part of the image memory control unit 102 will be described. FIG. 7 is a block diagram showing an outline of processing of the image memory / access control unit 221 of the image processing apparatus according to the present embodiment.
[0091]
In the block diagram of FIG. 7, the image memory access control unit 221 manages an image data interface with the parallel bus 220, and accesses the image data to the memory module 222, that is, stores (writes) / reads. It also controls the development of code data input from an external PC into image data.
[0092]
For this purpose, the image memory access control unit 221 includes a parallel data I / F 701, a system controller I / F 702, a memory access control unit 703, a line buffer 704, a video control unit 705, and a data compression unit 706. And a data decompression unit 707 and a data conversion unit 708.
[0093]
Here, the parallel data I / F 701 manages an interface of image data with the parallel bus 220. The memory access control unit 703 controls access of image data to the memory module 222, that is, storage (writing) / reading.
[0094]
The input code data is stored in the local area in the line buffer 704. The code data stored in the line buffer 704 is expanded into image data in the video control unit 705 based on the expansion processing instruction from the system controller 231 input via the system controller I / F 702.
[0095]
The expanded image data or the image data input from the parallel bus 220 via the parallel data I / F 701 is stored in the memory module 222. In this case, the data conversion unit 708 selects image data to be stored, the data compression unit 706 performs data compression to increase the memory usage efficiency, and the memory access control unit 703 sets the address of the memory module 222. Image data is stored (written) in the memory module 222 while being managed.
[0096]
When reading out the image data stored (accumulated) in the memory module 222, the memory access control unit 703 controls the read destination address, and the data expansion unit 707 expands the read image data. When the decompressed image data is transferred to the parallel bus 220, the data is transferred via the parallel data I / F 701.
[0097]
(Configuration of facsimile control unit 224)
Next, a functional configuration of the facsimile control unit 224 will be described. FIG. 8 is a block diagram showing the configuration of the facsimile control unit 224 of the image processing apparatus according to this embodiment.
[0098]
In the block diagram of FIG. 8, the facsimile control unit 224 includes a facsimile transmission / reception unit 801 and an external I / F 802. Here, the facsimile transmission / reception unit 801 converts the image data into a communication format and transmits it to the external line, and returns the data from the outside to the image data and creates it via the external I / F unit 802 and the parallel bus 220. Recorded and output in the image unit.
[0099]
The facsimile transmission / reception unit 802 includes a facsimile image processing unit 803, an image memory 804, a memory control unit 805, a data control unit 806, an image compression / decompression unit 807, a modem 808, and a network control device 809.
[0100]
Among these, regarding the facsimile image processing, the binary smoothing processing for the received image is performed in the edge smoothing processing unit 601 in the video data control unit 205 shown in FIG. As for the image memory 804, part of the output buffer function is transferred to the image memory access control unit 221 and the memory module 222.
[0101]
In the facsimile transmission / reception unit 801 configured as described above, when the transmission of the image data is started, the data control unit 806 instructs the memory control unit 805 to sequentially read out the image data accumulated from the image memory 804. The read image data is restored to the original signal by the facsimile image processing unit 803, density conversion processing and scaling processing are performed, and added to the data control unit 806.
[0102]
The image data added to the data control unit 806 is code-compressed by the image compression / decompression unit 807, modulated by the modem 808, and then sent to the destination via the network control device 809. Then, the image information for which transmission has been completed is deleted from the image memory 804.
[0103]
At the time of reception, the received image is temporarily stored in the image memory 804. If the received image can be recorded and output at that time, the received image is recorded and output when reception of one image is completed. When a call is started during the copying operation and reception starts, the image memory 804 is accumulated in the image memory 804 until the usage rate of the image memory 804 reaches a predetermined value, for example, 80%, and the usage rate of the image memory 1904 is increased to 80%. When it reaches, the writing operation being executed at that time is forcibly interrupted, and the received image is read from the image memory 804 and recorded and output.
[0104]
At this time, the received image read from the image memory 804 is deleted from the image memory 804, the writing operation that was interrupted when the usage rate of the image memory 804 has decreased to a predetermined value, for example, 10%, is resumed, and the writing operation is resumed. When all the operations are completed, the remaining received images are recorded and output. In addition, various parameters for the writing operation at the time of interruption are internally saved so that the writing operation can be resumed after being interrupted, and the parameters are internally restored at the time of resumption.
[0105]
(Contents of density conversion process)
Next, the contents of the density conversion process will be described. FIG. 9 is an explanatory diagram showing the contents of density conversion processing of the image processing apparatus according to the present embodiment.
[0106]
9, the image processing apparatus includes an image data control unit 203 and an image processing processor 204, an image input unit 901, an image storage unit 902, a first image output unit 903, an application unit 904, 2 image output unit 905.
[0107]
Here, the image input unit 901 is for inputting an image and includes the above-described image reading unit of FIG. Therefore, the function is realized by the reading unit 201 and the sensor board unit 202 shown in FIG. Further, the image input unit 901 may include a case where an image is input by a method other than input by image reading.
[0108]
Further, the image storage unit 902 has a page memory capable of recording data from the image data control unit 203. The recorded data can be output again to the image data control unit 203, and the data can be output in response to a request from another application. The configuration includes the image memory control unit shown in FIG. is there.
[0109]
Therefore, the function can be realized by the image memory access control unit 221 and the memory module 222 shown in the figure. The image storage unit 902 may include a storage medium such as an external storage device.
[0110]
The first image output unit 903 outputs an image and includes the above-described image writing unit 104 of FIG. Therefore, the function can be realized by the video data control unit 205 and the image forming unit (engine) 206 shown in FIG. Further, the first image output unit 903 is not limited to image writing, and may be an output form such as display or transmission of image data.
[0111]
The application unit 904 can receive data from the page memory in the image storage unit and output data to the second image output unit 905. In the present invention, the application unit exists as, for example, a facsimile application that can share the image storage unit 902.
[0112]
Further, the image data output from the second image output unit 905 is data compressed in the application unit 904, and a configuration that can be transferred by an analog line or the like is taken as an example. Therefore, the functions of the application unit 904 and the second output unit can be realized by the facsimile control unit 224 shown in FIG.
[0113]
The image data control unit 203 includes selectors 911 to 917, a main scanning density conversion unit 918, and a sub scanning density conversion unit 919. Further, the image processor 204 includes selectors 921 to 926, a main scanning density conversion unit 928, and a sub scanning density conversion unit 929. Further, the image processing processor 204 includes an input image processing unit 931 and an output image processing unit 941.
[0114]
In the image data control unit 203, the selector 911 receives the input of the image data from the image input unit 901, and transfers the image data to the next-stage image processor 204 unprocessed by making an a11-b11 connection. Further, the selector 911 can switch to a path so that density conversion processing is performed on the image data from the image input unit 901 by using the a11-c11 connection.
[0115]
The selector 912 can receive the image data input from the image storage unit 902 and transfer the image data to the next-stage image processor 204 unprocessed by making an a12-b12 connection. Further, the selector 912 can be switched to a path so as to perform density conversion processing on the image data from the image image storage unit 902, similarly to the selector 911, by using the a12-c12 connection.
[0116]
Similarly to the selectors 911 and 912, the selector 917 receives the input of the image data from the image processing processor 204 and establishes the a17-b17 connection, whereby the image data is unprocessed and the first image output unit 903 in the next stage. Can be transferred to. Further, by using the a17-c17 connection, it is possible to switch to a path so as to perform density conversion processing on the image data from the image processing processor 204.
[0117]
The data output by the selectors 911, 912, and 915 can be input to either main scanning density conversion or sub-scanning density conversion, and the selection is determined by the selector 913 and the selector 915.
[0118]
Input to the main scanning density conversion is image data from the image input unit 901 (when a11-c11 is connected) by the selector 913, and image data from the output image processing unit 941 of the image processor 204 (a17-c17 is connected). ), Image data from the image storage unit 902 (when a12-c12 is connected), or a kind of image data after sub-scanning density conversion processing (when d16 is connected later) (a13-e13 connection in the selector 913) , B13-e13 connection, c13-e13 connection, and d13-e13 connection) can be selected and transferred to the main scanning density conversion unit 918.
[0119]
The image data converted by the main scanning density conversion unit 918 is output by the selector 914 to the input image processing unit 931 of the image processing processor 204 (a14-e14 connection) and output to the image output unit (b14-e14 connection). ), Data output can be selected as either the output to the output image processing unit 941 of the image processor 204 (connection c14-e14) or the output to the sub-scanning density conversion unit 919 (connection d14-e14).
[0120]
Similarly, the selector 915 has four input data (a15-e15 connection (image data from the image input unit 901), b15-e15 connection (image data from the output image processing unit 941 of the image processor 204), and c15-e15. Data can be selected from the connection (image data from the image storage unit 902) and d15-e15 connection (image data after the main scanning density conversion process)), and the data can be transferred to the sub-scanning density conversion unit 919.
[0121]
Further, the output data of the image data after density conversion processing in the sub-scanning density conversion unit 919 can be selected from four outputs by the selector 916. That is, output to the input image processing unit 931 of the image processing processor 204 (a16-e16 connection), output to the image output unit (b16-e16 connection), output to the output image processing unit 941 of the image processing processor 204 (c16) -E16 connection) and data output (d16-e16 connection) can be selected as either output to the sub-scanning density conversion process.
[0122]
As described above, the selectors 913 to 916 can select only one of main scanning or sub-scanning density conversion processing of image data and set both main and sub density conversions.
[0123]
In the processing in the main scanning density conversion unit 918, when the density of the image input unit 901 is 600 dpi and the density of the first image output unit 903 is 1200 dpi, the input data is scaled by 200% in the main scanning direction. Thus, the data amount is doubled and transferred to the first image output unit 903, thereby enabling 600 dpi → 1200 dpi conversion.
[0124]
As described above, pixel complementation in zooming uses three-dimensional convolution or the like. Any density conversion is possible by changing the magnification. Also in the processing in the sub-scanning density conversion unit 919, similarly to the main scanning density conversion unit 918, the data amount in the sub-scanning direction is changed by changing the magnification in the sub-scanning direction, thereby realizing density conversion.
[0125]
In the image processor 204, the selector 921 receives the image data input from the image data control unit 203. The selector 921 performs image processing by the input by the input image processing unit 931 as a21-b21 connection, and outputs the processed image data to the image data control unit 203 again. Alternatively, it is possible to select switching to a path for performing density conversion processing on image data from the image data control unit 203 as a21-c21 connection.
[0126]
The data output from the selector 921 can be input to either the main scanning density conversion unit 928 or the sub scanning density conversion unit 929, and the main / sub selection is determined by the selector 923 and the selector 925. Input to the main scanning density conversion is performed by a selector 923 by image data input from the image data control unit 203 (a23-d23 connection), stored image data from the image data control unit 203 (b23-d23 connection), One type can be selected from the image data after the sub-scanning density conversion process (c23-d23 connection) and transferred to the main scanning density conversion unit 928.
[0127]
The image data after the conversion processing by the main scanning density conversion unit 928 is output by the selector 924 to the first image output unit 903 via the image processor 204 (a24-d24 connection), to the output image processing unit 941. Output (b24-d24 connection) and output to the sub-scanning density converter 929 (c24-d24 connection) can be selected.
[0128]
Similarly, the selector 925 has three input data (a25-d15 connection (image data input from the image data control unit 203), b25-d25 connection (stored image data from the image data control unit 203), c25. -D15 connection (image data after sub-scanning density conversion process)) is selected, and the data is transferred to the sub-scanning density conversion unit 929.
[0129]
Furthermore, the image data after density conversion processing in the sub-scanning density conversion unit 929 can be selected from three outputs by the selector 926. That is, output to the first image output unit 903 via the image processor 204 (a26-d26 connection), output to the output image processing unit 941 (b26-d26 connection), and output to the sub-scanning density conversion unit 929 Output (c26-d26 connection) can be selected.
[0130]
In this manner, the selectors 923 to 926 can select only one of main scanning or sub-scanning density conversion processing of image data and set both main and sub density conversions.
[0131]
The input image processing unit 931 performs image processing for the purpose of correcting the characteristics of the input means on the image from the image input unit 901 stage. Examples of image processing in the input image processing unit 931 include image processing such as shading processing, black level correction, and filters.
[0132]
The output image processing unit 941 performs image processing for the purpose of correcting the data from the image storage unit 902 according to the characteristics of the first image output unit 903. Examples of image processing in the output image processing unit 941 include γ conversion, error diffusion, dither processing, and the like.
[0133]
Next, the contents of a series of processes in which specific density conversion is performed will be described. FIG. 10 is an explanatory diagram showing the contents of a series of image processing with density conversion processing of the image processing apparatus according to the present embodiment.
[0134]
10, the image data control unit 203 is configured to perform density conversion processing 1000 on input data from the image input unit 901 in both the main scanning direction and the sub-scanning direction. Thereafter, input image processing in the input image processing unit 931, storage in the image storage unit 902, output image processing in the output image processing unit 941 are performed on the density-converted image data, and the image data is output to the first image output unit 903. .
[0135]
FIG. 11 is an explanatory diagram showing the contents of a table storing connection states of the selectors 911 to 926 of the image processing apparatus according to this embodiment.
[0136]
In the selectors 911 to 926 shown in FIG. 9, the selector 911 has an a11-c11 connection, the selector 912 has an a12-b12 connection, the selector 913 has an a13-e13 connection, the selector 914 has a d14-e14 connection, and the selector 915 has As shown in FIG. 10, d15-e15 connection, selector 916 is a16-e16 connection, selector 917 is a17-b17 connection, selector 921 is a21-b21 connection, and selector 922 is a22-cb22 connection. It can be configured.
[0137]
At that time, the selectors 923, 224, 225, and 926 are not used. Therefore, it is preferable that none of these selectors be selected. Either the main scanning density conversion or the sub-scanning density conversion may be performed first. Therefore, the connection 1 in FIG. 11 performs the main scanning density conversion first, and the connection 2 performs the sub scanning density conversion first.
[0138]
Next, a flow of a series of processing of image data in the configuration shown in FIG. 10 will be described. FIG. 12 is a flowchart showing a flow of a series of processes in FIG. 10 (first half of the process). In the flowchart of FIG. 12, the image input unit 901 inputs image data (step S1201), and transmits the input image data to the image data control unit 203 (step S1202).
[0139]
Next, the image data control unit 203 receives the image data transmitted in step S1202 (step S1203). Thereafter, density conversion in the main scanning direction (step S1204) and density conversion in the sub-scanning direction (step S1205) are performed on the received image data.
[0140]
Note that the order of step S1203 and step S1204 may be reversed. Further, the image data control unit 203 transmits the image data subjected to the density conversion to the image processing processor 204 (step S1206).
[0141]
The image processor 204 receives the image data transmitted in step S1206 (step S1207). Next, the input image processing unit 931 performs input image processing (step S1208). Thereafter, the image processing processor 204 transmits again the image data that has undergone the input image processing to the image data control unit 203 (step S1209).
[0142]
The image data control unit 203 receives the image data transmitted in step S1209, and transmits the received image data as it is to the image storage unit 902 (step S1210).
[0143]
The image storage unit 902 receives the image data transmitted in step S1210 (step S1211), and writes the received image data (step S1212), thereby completing a series of processing (first half part).
[0144]
FIG. 13 is a flowchart showing a flow of a series of processes in FIG. 10 (second half of the process). In the flowchart of FIG. 13, the image storage unit 902 reads image data (step S1301), and transmits the read image data to the image data control unit 203 (step S1302).
[0145]
The image data control unit 203 receives the image data transmitted in step S1302, and transmits the received image data as it is to the image processing processor 204 (step S1303).
[0146]
The image processor 204 receives the image data transmitted in step S1304 (step S1304). Next, the output image processing unit 941 performs output image processing (step S1305). Thereafter, the image processor 204 transmits the image data on which the output image processing has been performed to the image data control unit 203 again (step S1306).
[0147]
The image data control unit 203 receives the image data transmitted in step S1306, and transmits the received image data as it is to the first image output unit 903 (step S1307).
[0148]
The first image output unit 903 receives the image data transmitted in step S1307 (step S1308), and outputs the received image data (step S1309), thereby completing the series of processes (second half).
[0149]
As described above, by performing image processing in the image processor 204 on the density-converted image, optimum input in the input image processing unit 931 and output image processing unit 941 is performed on the image data after density conversion. Output image processing can be performed, and image data after density conversion can be provided to the image storage unit 902.
[0150]
Next, another content of a series of image processing with density conversion processing will be described. FIG. 14 is an explanatory diagram showing another content of a series of image processing with density conversion processing.
[0151]
In FIG. 14, the image data control unit 203 performs density conversion processing 1400 in both the main scanning direction and the sub-scanning direction on the image data after the output image processing by the output image processing unit 941 of the image processing processor 204. Take. The previous data is subjected to input image processing, storage (writing) in the image storage unit, and output image processing as image data before density conversion.
[0152]
FIG. 15 is an explanatory diagram showing the contents of a table storing other connection states of the selectors 911 to 926.
[0153]
In the selectors 911 to 926 shown in FIG. 15, the selector 911 has an a11-b11 connection, the selector 912 has an a12-b12 connection, the selector 913 has a b13-e13 connection, the selector 914 has a d14-e14 connection, and the selector 915 has As shown in FIG. 14, d15-e15 connection, selector 916 is b16-e16 connection, selector 917 is a17-c17 connection, selector 921 is a21-b21 connection, and selector 922 is a22-bb22 connection. It can be configured.
[0154]
Similar to the configuration in FIG. 10, either the main scanning density conversion or the sub-scanning density conversion may be performed first. Therefore, the connection 1 in FIG. 15 performs the main scanning density conversion first, and the connection 2 performs the sub scanning density conversion first.
[0155]
Next, a flow of a series of processing of image data in the configuration shown in FIG. 14 will be described. FIG. 16 is a flowchart showing a flow of a series of processes (first half of the process) in FIG. In the flowchart of FIG. 16, the image input unit 901 inputs image data (step S1601), and transmits the input image data to the image data control unit 203 (step S1602).
[0156]
Next, the image data control unit 203 receives the image data transmitted in step S1602, and transmits it to the image processing processor 204 as it is (step S1603).
[0157]
The image processor 204 receives the image data transmitted in step S1603 (step S1604). Next, the input image processing unit 931 performs input image processing (step S1607). Thereafter, the image processor 204 transmits again the image data that has undergone the input image processing to the image data control unit 203 (step S1608).
[0158]
The image data control unit 203 receives the image data transmitted in step S1608 and transmits it as it is to the image storage unit 902 (step S1609).
[0159]
The image storage unit 902 receives the image data transmitted in step S1609 (step S1610), and writes the received image data (step S1611), thereby ending a series of processing (first half part).
[0160]
FIG. 17 is a flowchart showing a flow of a series of processes in FIG. 14 (second half of the process). In the flowchart of FIG. 17, the image storage unit 902 reads image data (step S1701), and transmits the read image data to the image data control unit 203 (step S1702).
[0161]
The image data control unit 203 receives the image data transmitted in step S1702 and transmits it as it is to the image processing processor 204 (step S1703).
[0162]
The image processor 204 receives the image data transmitted in step S1304 (step S1704). Next, the output image processing unit 941 performs output image processing (step S1705). Thereafter, the image processor 204 transmits the image data on which the output image processing has been performed to the image data controller 203 again (step S1706).
[0163]
Next, the image data control unit 203 receives the image data transmitted in step S1706 (step S1707). Thereafter, density conversion in the main scanning direction (step S1708) and density conversion in the sub-scanning direction (step S1709) of the received image data are performed.
[0164]
Note that the order of step S1708 and step S1709 may be reversed. Further, the image data control unit 203 transmits the image data subjected to density conversion to the first image output unit 903 (step S1710).
[0165]
The first image output unit 903 receives the image data transmitted in step S1710 (step S1711), and outputs the received image data (step S1712), thereby completing a series of processes (second half part).
[0166]
As described above, when performing density conversion that increases the amount of image data, the processing load on the image processor 204 can be reduced, the storage capacity of the image storage unit 902 can be reduced, and the image A data transfer amount between the processing processor 204 and the image data control unit 203 can be reduced.
[0167]
Next, still another content of a series of image processing with density conversion processing will be described. FIG. 18 is an explanatory diagram showing another content of a series of image processing with density conversion processing.
[0168]
In FIG. 18, the image data control unit 203 performs a density conversion process 1800 on the received data from the image storage unit 902 in both the main scanning direction and the sub-scanning direction. The previous data is subjected to input image processing in the input image processing unit 931 and writing to the image storage unit 902 as image data before density conversion, and output by the output image processing unit 941 for the image data after density conversion. Perform image processing.
[0169]
FIG. 19 is an explanatory diagram showing the contents of a table storing other connection states of the selectors 911 to 926.
[0170]
In the selectors 911 to 926 shown in FIG. 9, the selector 911 has an a11-b11 connection, the selector 912 has an a12-c12 connection, the selector 913 has a c13-e13 connection, the selector 914 has a d14-e14 connection, and the selector 915 has a selector 915. As shown in FIG. 18, d15-e15 connection, selector 916 is c16-e16 connection, selector 917 is a17-c17 connection, selector 921 is a21-b21 connection, and selector 922 is a22-b22 connection. It can be configured.
[0171]
Similar to the configuration in FIG. 10, either the main scanning density conversion or the sub-scanning density conversion may be performed first. Therefore, in connection 1 in FIG. 19, the main scanning density conversion is performed first, and in connection 2, the sub-scanning density conversion is performed first.
[0172]
Next, a flow of a series of processing of image data in the configuration shown in FIG. 18 will be described. FIG. 20 is a flowchart showing a flow of a series of processes in FIG. 18 (second half of the process). Note that the flowchart of the first half of the processing is the same as the flowchart shown in FIG.
[0173]
In the flowchart of FIG. 20, the image storage unit 902 reads image data (step S2001), and transmits the read image data to the image data control unit 203 (step S2002).
[0174]
Next, the image data control unit 203 receives the image data transmitted in step S2002 (step S2003). Thereafter, density conversion in the main scanning direction (step S2004) and density conversion in the sub-scanning direction (step S2005) are performed on the received image data.
[0175]
Note that the order of step S2003 and step S2004 may be reversed. Further, the image data control unit 203 transmits the image data subjected to density conversion to the image processing processor 204 (step S2006).
[0176]
The image processor 204 receives the image data transmitted in step S2006 (step S2007). Next, the output image processing unit 941 performs output image processing (step S2008). Thereafter, the image processor 204 transmits the image data on which the output image processing has been performed to the image data control unit 203 again (step S2009).
[0177]
The image data control unit 203 receives the image data transmitted in step S2009 and transmits it as it is to the first image output unit 903 (step S2010).
[0178]
The first image output unit 903 receives the image data transmitted in step S2010 (step S2011), and outputs the received image data (step S2012), thereby completing a series of processes (second half).
[0179]
As described above, by performing image processing in the output image processing unit 941 on the image after density conversion, it is possible to perform optimum output image processing on the image data after density conversion. When performing density conversion that increases the amount of data, the storage capacity of the image storage unit 902 can be reduced.
[0180]
Next, still another content of a series of image processing with density conversion processing will be described. FIG. 21 is an explanatory diagram showing another content of a series of image processing with density conversion processing.
[0181]
In FIG. 21, the image data control unit 203 performs density conversion processing 2100 in either the main scanning direction or the sub-scanning direction on the input data from the image input unit 901, and the image processing processor 204 performs the preceding stage. The image data control unit 203 is configured to perform density conversion processing 2101 in either the main scanning direction or the sub-scanning direction that has not been subjected to density conversion. Thereafter, input image processing, storage in the image storage unit, and output image processing are performed on the density-converted image data, and the image data is output to the first image output unit 903.
[0182]
FIG. 22 is an explanatory diagram showing the contents of a table storing other connection states of the selectors 911 to 926.
[0183]
In the selectors 911 to 916 shown in FIG. 22, the selector 911 is connected to a11-b11, the selector 912 is connected to a12-c12, the selector 913 is connected to c13-e13, and the selector 914 is connected to d14-e14.
[0184]
Further, the selector 917 is connected to a17-b17, the selector 921 is connected to a21-b21, the selector 922 is connected to a22-b22, the selector 925 is connected to b25-d25, and the selector 926 is connected to b26-d26. The configuration shown in FIG. 21 can be adopted.
[0185]
In connection 1 in FIG. 22, main scanning density conversion processing is performed in the image data control unit 203, and sub-scanning density conversion processing is performed in the image processing processor 204. On the other hand, in connection 2, on the contrary, the main scanning density conversion process is performed in the image processing processor 204, and the sub-scanning density conversion process is performed in the image data control unit 203.
[0186]
Next, a flow of a series of processing of image data in the configuration shown in FIG. 21 will be described. FIG. 23 is a flowchart showing a flow of a series of processes in FIG. 21 (second half of the process). Note that the flowchart of the first half of the processing is the same as the flowchart shown in FIG.
[0187]
In the flowchart of FIG. 23, the image storage unit 902 reads image data (step S2301), and transmits the read image data to the image data control unit 203 (step S2302).
[0188]
Next, the image data control unit 203 receives the image data transmitted in step S2302 (step S2303). Thereafter, only density conversion in the main scanning direction of the received image data is performed (step S2304). Further, the image data control unit 203 transmits the image data subjected to density conversion to the image processing processor 204 (step S2305).
[0189]
The image processor 204 receives the image data transmitted in step S2305 (step S2306). Thereafter, only the density conversion in the sub-scanning direction in which the density conversion has not been performed in the received image data is performed (step S2307).
[0190]
Next, the output image processing unit 941 performs output image processing (step S2308). Thereafter, the image processor 204 transmits again the image data on which the output image processing has been performed to the image data control unit 203 (step S2309).
[0191]
The image data control unit 203 receives the image data transmitted in step S2309 and transmits it as it is to the first image output unit 903 (step S2310).
[0192]
The first image output unit 903 receives the image data transmitted in step S2310 (step S2311), and outputs the received image data (step S2312), thereby completing a series of processes (second half).
[0193]
FIG. 24 is a flowchart showing another flow (second half of the processing) of the series of processing in FIG. In FIG. 24, the image data control unit 203 performs density conversion in the sub-scanning direction instead of density conversion in the main scanning direction (step S2404).
[0194]
The image processor 204 performs density conversion in the main scanning direction instead of performing sub-scanning density conversion (step S2407). The other processes are the same as those in the flowchart shown in FIG. Thus, the density conversion process in the main scanning direction and the density conversion process in the sub-scanning direction can be performed by separate units.
[0195]
As described above, the processing amount of both the image data control unit 203 and the image processing processor 204 can be reduced, and by performing image processing in the output image processing unit 941 on the image after density conversion, Optimal output image processing can be performed on the image data after density conversion, and the storage capacity of the image storage unit 902 can be reduced when performing density conversion that increases the amount of image data. .
[0196]
Next, still another content of a series of image processing with density conversion processing will be described. FIG. 25 is an explanatory diagram showing another content of a series of image processing with density conversion processing.
[0197]
In FIG. 25, the image data control unit 203 performs density conversion processing 2500 in either the main scanning direction or the sub-scanning direction on the input data from the image input unit 901, and the image processing processor 204 performs the preceding stage. The image data control unit 203 is configured to perform density conversion processing 2501 in either the main scanning direction or the sub-scanning direction that has not been subjected to density conversion. Thereafter, input image processing, storage in the image storage unit, and output image processing are performed on the density-converted image data, and the image data is output to the first image output unit 903.
[0198]
FIG. 26 is an explanatory diagram showing the contents of a table storing other connection states of the selectors 911 to 926.
[0199]
In the selectors 911 to 926 shown in FIG. 22, the selector 911 is connected to a11-c11, the selector 912 is connected to a12-c12, the selector 913 is connected to a13-e13, and the selector 914 is connected to a14-e14.
[0200]
Further, the selector 917 is connected to a17-b17, the selector 921 is connected to a21-c21, the selector 922 is connected to a22-c22, the selector 925 is connected to a25-d25, and the selector 926 is connected to a26-d26. The configuration shown in FIG. 25 can be adopted.
[0201]
In connection 1 in FIG. 26, the main scanning density conversion process is performed in the image data control unit 203, and the sub-scanning density conversion process is performed in the image processing processor 204. On the other hand, in connection 2, on the contrary, the main scanning density conversion process is performed in the image processing processor 204, and the sub-scanning density conversion process is performed in the image data control unit 203.
[0202]
Next, a flow of a series of processing of image data in the configuration shown in FIG. 25 will be described. FIG. 27 is a flowchart showing a flow of a series of processes (first half of the process) in FIG. Note that the flowchart of the latter half of the process has the same contents as the flowchart shown in FIG.
[0203]
In the flowchart of FIG. 27, the image input unit 901 inputs image data (step S2701), and transmits the input image data to the image data control unit 203 (step S2702).
[0204]
Next, the image data control unit 203 receives the image data transmitted in step S2702 (step S2703). Thereafter, only density conversion processing 2500 in the main scanning direction of the received image data is performed (step S2704). Further, the image data control unit 203 transmits the image data subjected to the density conversion to the image processing processor 204 (step S2705).
[0205]
The image processor 204 receives the image data transmitted in step S2705 (step S2706). Thereafter, only the density conversion processing 2501 in the sub-scanning direction in which the density conversion has not been performed in the received image data is performed (step S2707).
[0206]
Next, the input image processing unit 931 performs input image processing (step S2708). Thereafter, the image processor 204 transmits again the image data on which the input image processing has been performed to the image data control unit 203 (step S2709).
[0207]
The image data control unit 203 receives the image data transmitted in step S2709, and transmits the received image data as it is to the image storage unit 902 (step S2710).
[0208]
The image storage unit 902 receives the image data transmitted in step S2710 (step S2711), and writes the received image data (step S2712), thereby completing a series of processing (first half part).
[0209]
FIG. 28 is a flowchart showing another flow of the series of processes in FIG. 25 (first half of the process). In FIG. 28, the image data control unit 203 performs density conversion in the sub-scanning direction instead of density conversion in the main scanning direction (step S2804).
[0210]
The image processor 204 performs density conversion in the main scanning direction instead of performing sub-scanning density conversion (step S2807). The other processes are the same as those in the flowchart shown in FIG. Thus, the density conversion process in the main scanning direction and the density conversion process in the sub-scanning direction can be performed by separate units.
[0211]
As described above, the processing amount of both the image data control unit 203 and the image processing processor 204 can be reduced, and the image in the input image processing unit 231 and the output image processing unit 241 with respect to the image after density conversion. By performing the processing, the optimum input / output image processing can be performed on the image data after density conversion, and the image data after density conversion can be provided to the image storage unit 902.
[0212]
Next, the contents of a series of processes of the image data control unit 203 of the image processing apparatus according to the present embodiment will be described. FIG. 29 and FIG. 30 are flowcharts showing a series of flows of the image processing apparatus according to the present embodiment.
[0213]
In the flowchart of FIG. 29, the image data control unit 203 first determines whether image data has been acquired (step S2901). Here, when the image data is acquired after waiting for the acquisition of the image data (Yes in step S2901), the image data control information is acquired (step S2902).
[0214]
Next, based on the image data control information acquired in step S2902, it is determined whether or not to perform density conversion in the main scanning direction of the acquired image data (step S2903).
[0215]
If it is determined in step S2903 that density conversion in the main scanning direction is to be performed (Yes in step S2903), density conversion in the main scanning direction is executed (step S2904). On the other hand, if it is determined in step S2903 that density conversion in the main scanning direction is not performed (No in step S2903), the process proceeds to step S2905 without doing anything.
[0216]
In step S2905, based on the image data control information acquired in step S2902, it is determined whether or not to perform density conversion in the sub-scanning direction of the acquired image data (step S2905).
[0217]
If it is determined in step S2905 that density conversion in the sub-scanning direction is to be performed (Yes in step S2905), density conversion in the sub-scanning direction is executed (step S2906). On the other hand, if it is determined in step S2906 that density conversion in the sub-scanning direction is not performed (No in step S2906), the process proceeds to step S2907 without doing anything.
[0218]
In step S2907, the transmission destination of the image data is determined based on the image data control information acquired in step S2902. Thereafter, the data is transmitted to the determined transmission destination (step S2908), the series of processes is terminated, and then the process proceeds to step S2901 to wait for acquisition of new image data.
[0219]
In the flowchart of FIG. 30, the image data control unit 203 first determines whether image data has been acquired (step S3001). If the image data is acquired after waiting for the acquisition of the image data (Yes in step S3001), it is next determined whether or not image data control information has been input (step S3002).
[0220]
The input of the image data control information is performed, for example, when the operator inputs from the operation panel 234. The image data control information may directly specify at what timing the density conversion should be performed by the processing unit, or may only input the type of image data. When only the type of image data is input, it may be determined which processing unit or at which timing the density conversion is performed based on the type of image data.
[0221]
In step S3002, the input of the image data control information is awaited. If there is an input (Yes in step S3002), the process proceeds to step S2903 shown in FIG.
[0222]
As described above, the image processing apparatus according to the present embodiment can freely set the order in which the density conversion processing is performed, thereby preventing the deterioration of the image, the amount of data transferred between the units, Data processing amount (processing load) and storage capacity of image memory can be reduced. Therefore, it is possible to control the density conversion process optimal for the entire system.
[0223]
Note that the image processing method described in this embodiment can be realized by executing a program prepared in advance on a computer such as a personal computer or a workstation. This program is recorded on a computer-readable recording medium such as a hard disk, floppy disk, CD-ROM, MO, and DVD, and is executed by being read from the recording medium by the computer. The program can be distributed via the recording medium and a network such as the Internet.
[0224]
【The invention's effect】
As described above, according to the first aspect of the present invention, image data can be processed. Edit processing And a first density conversion means for converting the density of the image data in the main scanning direction, and a second density conversion means for converting the density of the image data in the sub-scanning direction. And in front The image data control means First image data read by image reading means for reading image data , Second image data read by image memory control means for controlling image memory to write / read image data , Third image data subjected to image processing by the image processing means , At least one of the image data Receive Received image data The image memory control means , The image processing means , Transfer image data on paper Image writing means for writing Either And send to Received image data A third density converting means for converting the density in the main scanning direction and a fourth density converting means for converting the density in the sub scanning direction of the received image data. And the selecting means includes For each image data, a density conversion means for converting the density of each image data is selected from the first to fourth density conversion means. , Since only the density conversion means selected by the selection means converts the density of each image data, the order in which the density conversion processing is performed can be freely set.
[0225]
As a result, it is possible to prevent image deterioration and reduce the amount of data transferred between units, the amount of data processing (processing load), and the storage capacity of the image memory. Therefore, there is an effect that an image processing apparatus capable of controlling the density conversion process optimal for the entire system can be obtained.
[0226]
According to a second aspect of the present invention, in the first aspect of the invention, the image processing means applies the first image data read by the image reading means. Edit processing At least one of the first image processing means for applying the first image processing means and the first to third image data transmitted to the image writing means Edit processing The second image processing means for performing the optimum image processing by separately performing the input image processing and the output image processing on the image data, and thereby the optimum for the entire system. An effect is obtained in that an image processing apparatus capable of controlling density conversion processing is obtained.
[0227]
According to a third aspect of the present invention, in the first or second aspect of the present invention, the selection unit sets the density in the main scanning direction of the first image data read by the image reading unit. The density is converted by the third density conversion unit and the density of the first image data read by the image reading unit is selected so that the fourth density conversion unit converts the density. By performing image processing on the image, optimal input / output image processing can be performed on the image data after density conversion, and the image data after density conversion is provided to the image memory control means. As a result, an image processing apparatus capable of controlling the density conversion process optimal for the entire system can be obtained.
[0228]
According to the invention described in claim 4, in the invention described in claim 1 or 2, the selection unit performs main conversion of the third image data to be transmitted to the image writing unit, and the image Since the density in the sub-scanning direction of the third image data to be transmitted to the writing means is selected so that the fourth density converting means converts the image, the image data can be converted when the density conversion is performed to increase the amount of image data. The processing load on the processing means can be reduced, the storage capacity of the image memory controlled by the image memory control means can be reduced, and the data transfer amount between the image processing means and the image data control means can be reduced. As a result, an image processing apparatus capable of controlling the density conversion process optimal for the entire system can be obtained.
[0229]
According to the invention described in claim 5, in the invention described in claim 1 or 2, the density in the main scanning direction of the second image data transmitted from the selection means to the image processing means is the first. Since the density conversion unit 3 selects the density in the sub-scanning direction of the second image data to be converted and transmitted to the image processing unit, the fourth density conversion unit converts the density into the image after density conversion. By performing output image processing on the image data, it is possible to perform optimal image processing on the image data after density conversion, and when performing density conversion that increases the amount of image data, image memory control means As a result, it is possible to reduce the storage capacity of the image memory controlled by the image processing apparatus, thereby obtaining an image processing apparatus capable of controlling the optimum density conversion processing for the entire system.
[0230]
According to the invention described in claim 6, in the invention described in claim 1 or 2, the density in the main scanning direction or the sub-scanning of the second image data transmitted from the selection means to the image processing means. Any one of the density in the direction is converted by the third density conversion unit or the fourth density conversion unit, and density conversion is performed out of the density in the main scanning direction or the density in the sub scanning direction of the second image data. Since the density in the scanning direction that has not been selected is selected to be converted by the first density conversion unit or the second density conversion unit, the processing amount of both the image data control unit and the image processing unit can be reduced. By performing output image processing on the density-converted image, optimum image processing can be performed on the density-converted image data, and the density of the image data increases. When performing conversion, it is possible to reduce the storage capacity of the image memory controlled by the image memory control means, thereby obtaining an image processing apparatus capable of controlling density conversion processing optimal for the entire system. Play.
[0231]
According to a seventh aspect of the present invention, in the first or second aspect of the invention, the selection unit is configured such that the density in the main scanning direction of the first image data read by the image reading unit or the sub-scanning direction. Either one of the densities in the scanning direction is converted by the third density converting unit or the fourth density converting unit, and the density of the second image data in the main scanning direction or in the sub-scanning direction is the density. Since the density in the scanning direction that has not been converted is selected to be converted by the first density conversion means or the second density conversion means, the processing amount of both the image data control means and the image processing means can be reduced. In addition, by performing image processing on the image after density conversion, it is possible to perform optimum input / output image processing on the image data after density conversion, and image memory control means Can provide image data after the density conversion for, thereby, an effect that overall optimum density conversion processing control capable image processing apparatus of the system is obtained.
[0232]
According to the invention described in claim 8, in the invention described in claims 1-7, the image data control information including information on the contents of the processing for the first to third image data is further acquired. An image data information acquisition unit, and the selection unit selects the density conversion unit based on the image data control information acquired by the image data information acquisition unit, so that the operator can freely perform the density conversion procedure. It is possible to set and change, thereby obtaining an effect of obtaining an image processing apparatus capable of controlling the optimum density conversion processing for the entire system.
[Brief description of the drawings]
FIG. 1 is a block diagram functionally showing the configuration of an image processing apparatus according to an embodiment of the present invention.
FIG. 2 is a block diagram showing an example of a hardware configuration of the image processing apparatus according to the present embodiment.
FIG. 3 is a block diagram showing an outline of processing of an image processing processor of the image processing apparatus according to the present embodiment;
FIG. 4 is a block diagram showing an internal configuration of an image processing processor of the image processing apparatus according to the present embodiment.
FIG. 5 is a block diagram showing an outline of processing of an image data control unit of the image processing apparatus according to the present embodiment;
FIG. 6 is a block diagram showing an outline of video data processing of the image processing apparatus according to the present embodiment;
FIG. 7 is a block diagram showing an outline of processing of an image memory access control unit of the image processing apparatus according to the present embodiment;
FIG. 8 is a block diagram showing a configuration of a facsimile control unit of the image processing apparatus according to the present embodiment.
FIG. 9 is an explanatory diagram showing the contents of density conversion processing of the image processing apparatus according to the present embodiment;
FIG. 10 is an explanatory diagram showing the contents of a series of image processing with density conversion processing of the image processing apparatus according to the present embodiment;
FIG. 11 is an explanatory diagram showing the contents of a table storing connection states of selectors in the image processing apparatus according to the present embodiment;
12 is a flowchart showing a flow of a series of processes in FIG. 10 (first half of the process).
13 is a flowchart showing a flow of a series of processes in FIG. 10 (second half of the process).
FIG. 14 is an explanatory diagram showing another content of a series of image processing with density conversion processing of the image processing apparatus according to the present embodiment;
FIG. 15 is an explanatory diagram showing the contents of a table storing other connection states of selectors of the image processing apparatus according to the present embodiment;
16 is a flowchart showing a flow of a series of processes in FIG. 14 (first half of the process).
17 is a flowchart showing a flow of a series of processes in FIG. 14 (second half of the process).
FIG. 18 is an explanatory diagram showing another content of a series of image processing with density conversion processing of the image processing apparatus according to the present embodiment;
FIG. 19 is an explanatory diagram showing the contents of a table storing other connection states of selectors of the image processing apparatus according to the present embodiment;
20 is a flowchart showing a flow of a series of processes in FIG. 18 (second half of the process).
FIG. 21 is an explanatory diagram showing another content of a series of image processing with density conversion processing of the image processing apparatus according to the present embodiment;
FIG. 22 is an explanatory diagram showing the contents of a table storing other connection states of selectors of the image processing apparatus according to the present embodiment;
23 is a flowchart showing a flow of a series of processes in FIG. 21 (second half of the process).
24 is a flowchart showing another flow of the series of processing in FIG. 21 (second half of the processing).
FIG. 25 is an explanatory diagram showing another content of a series of image processing with density conversion processing of the image processing apparatus according to the present embodiment;
FIG. 26 is an explanatory diagram showing the contents of a table storing other connection states of selectors of the image processing apparatus according to the present embodiment;
FIG. 27 is a flowchart showing a flow of a series of processes in FIG. 21 (first half of the process).
FIG. 28 is a flowchart showing another flow of the series of processing in FIG. 21 (first half of processing).
FIG. 29 is a flowchart showing a series of flows of the image processing apparatus according to the present embodiment.
FIG. 30 is a flowchart showing another series of flows of the image processing apparatus according to the present embodiment.
FIG. 31 is a block diagram showing a hardware configuration of a digital multi-function peripheral according to the prior art.
[Explanation of symbols]
100 Image data control unit
101 Image reading unit
102 Image memory control unit
103 Image processing unit
104 Image writing unit
201 Reading unit
202 Sensor board unit
203 Image data control unit
204 Image processor
205 Video data controller
206 Imaging unit (engine)
210 Serial bus
211 Process controller
212,232 RAM
213,233 ROM
220 Parallel bus
221 Image memory access controller
222 Memory module
223 Personal computer (PC)
224 Facsimile control unit
225 Public line
231 System Controller
234 Operation panel
301, 303, 304, 306 Interface (I / F)
302 Scanner image processing unit
305 Output image processing unit
307 Command control unit
501 Image data input / output control unit
502 Image data input control unit
503 Data compression unit
504 Data converter
505, 603, 701 Parallel data I / F
506 Data decompression unit
507 Image data output control unit
601 Edge smoothing processing unit
602 Pulse control unit
604 Serial data I / F
605 Data converter
702 System controller I / F
703 Memory access control unit
704 line buffer
705 video controller
706 Data compression unit
707 Data decompression unit
708 Data converter
801 Facsimile transceiver
802 External I / F
803 Facsimile image processor
804 Image memory
805 Memory control unit
806 Data control unit
807 Image compression / decompression unit
808 modem
809 Network control device
901 Image input unit
902 Image storage unit
903 First image output unit
904 Application Department
905 Second image output unit
911, 912, 913, 914, 915, 916, 917, 921, 922, 923, 924, 925, 926 selector
918,928 Main scanning density converter
919, 929 Sub-scanning density converter
931 Input image processing unit
941 Output image processing unit

Claims (8)

An image processing apparatus comprising an image processing means, an image data control means, and a selection means,
The image processing means includes
While processing and editing the image data,
First density conversion means for converting the density of the image data in the main scanning direction; and second density conversion means for converting the density of the image data in the sub-scanning direction;
The image data control means includes
First image data read by image reading means for reading image data, second image data read by image memory control means for controlling image memory to write / read image data, said image processing means Receiving at least one of the third image data subjected to the image processing according to
The received image data is transmitted to any of the image memory control means, the image processing means, and the image writing means for writing the image data on the transfer paper,
A third density conversion means for converting the density of the received image data in the main scanning direction; and a fourth density conversion means for converting the density of the received image data in the sub-scanning direction;
The selection means includes
For each image data, among the first to fourth density conversion means, select a density conversion means for converting the density of each image data,
Only the density conversion means selected by the selection means converts the density of each image data. The image processing means includes
First image processing means for performing processing and editing processing on the first image data read by the image reading means;
Second image processing means for performing processing and editing processing on at least one of the first to third image data transmitted to the image writing means;
The image processing apparatus according to claim 1, further comprising: The selection means includes
The density in the main scanning direction of the first image data read by the image reading means is converted by the third density conversion means, and the density in the sub-scanning direction of the first image data read by the image reading means. The image processing apparatus according to claim 1, wherein the fourth density conversion unit converts the image data so as to be converted. The selection means includes
The density in the main scanning direction of the third image data to be transmitted to the image writing means is converted by the third density converting means, and the density in the sub-scanning direction of the third image data to be transmitted to the image writing means. The image processing apparatus according to claim 1, wherein the fourth density conversion unit converts the image data so as to be converted. The selection means includes
The density in the main scanning direction of the second image data to be transmitted to the image processing means is converted by the third density converting means, and the density in the sub-scanning direction of the second image data to be transmitted to the image processing means is The image processing apparatus according to claim 1, wherein the fourth density conversion unit is selected to perform conversion. The selection means includes
The third density conversion means or the fourth density conversion means converts either the density in the main scanning direction or the density in the sub scanning direction of the second image data to be transmitted to the image processing means, and Of the two image data densities in the main scanning direction or sub-scanning direction, the density in the scanning direction that has not been density-converted is selected so that the first density converting means or the second density converting means converts the density. The image processing apparatus according to claim 1, wherein: The selection means includes
The third density converting means or the fourth density converting means converts either the density in the main scanning direction or the density in the sub scanning direction of the first image data read by the image reading means, Of the densities in the main scanning direction or the sub-scanning direction of the first image data , the density in the scanning direction that has not been subjected to the density conversion is selected so that the first density conversion unit or the second density conversion unit converts the density. The image processing apparatus according to claim 1, wherein the image processing apparatus is an image processing apparatus. Furthermore, the image data information acquisition means for acquiring image data control information including information related to the content of processing for the first to third image data,
The image processing apparatus according to claim 1, wherein the selection unit selects the density conversion unit based on image data control information acquired by the image data information acquisition unit.

Images