JP2009177255A - Image processing system and image processing device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an image processing system with two or more image processing devices having a data accumulating function coupled together via a communication means, attaining both image data originality management and its efficient sharing. <P>SOLUTION: The image processing device A18 on the communication source acquires image processing information, management information describing the possibility of data accumulation in the image processing device B19 on the communication sink and data content, and incidental information from a user and transmits them together with the processed image data, in image data transmission to the image processing device B19 on the communication sink via a network 17, The image processing device on the communication sink accumulates or deletes the image data, based on the management information. When accumulating the image data or incidental information, the management information is accumulated in the image processing device B19 on the communication source to be referred to, when the accumulated data are used as a coupling operation. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention is an image processing apparatus that handles digital image data, such as a digital copying machine, a facsimile, a printer, a scanner, and a digital multi-function peripheral (MFP), and communicates between a plurality of image processing apparatuses connected via a network. The present invention relates to an image processing system for processing image data and an image processing apparatus used in the system.

  In recent years, with the development of a reading device using a line sensor composed of a CCD photoelectric conversion element and a toner writing device using laser irradiation, a digital copying machine for creating a copy with image data digitized from an analog copying machine has appeared.

  Since becoming a digital copier, compatibility with other devices that handle digital image data has increased, and not only functions as a copier, but also combined with various functions such as facsimile function, printer function, scanner function, Instead of just a digital copier, it came to be called MFP. In addition, the capacity and cost of storage devices such as memories and HDDs are increased, the speed and spread of communication technologies such as networks, the processing performance of CPUs, the technology related to digital image data (compression technology, etc.), etc. With the evolution of technologies related to, the functions that are installed are also diversifying.

  The importance of information value in business is already recognized, and it is required not only to convey information quickly, accurately and reliably, but also to convey it in an easy-to-understand manner and effectively. With the speed and spread of communication technology, memory capacity / cost reduction / miniaturization, and PC performance improvements, new functions for efficiently handling information using digital data have been provided. The provision and integration of new functions is also desired for MFPs that handle digital image data, which is a part of the above.

  For example, as seen in Patent Document 1, a certain image processing apparatus is connected to one or more other image processing apparatuses via communication means, and the image data read by the former image processing apparatus is referred to as the former. An image processing connection system is known in which the productivity of copying can be improved by printing (connection operation) with both of the latter image processing apparatuses. In recent image processing connection systems, multi-functionalization such as double-sided copying, sorting, and stapling has been proposed.

  Further, Patent Document 2 proposes an image processing system that is devised to further improve the productivity in consideration of the usage status of the user and the priority in operation. Also, in Patent Document 3, for an MFP having a BOX function (image storage function) for reusing used image data, another BOX function connected to the network to effectively use the BOX function. As a parent-child relationship.

At this time, as the authority on the parent side, transfer destination registration to the child can be performed, and data can be transferred according to the registration status. The child side can select how the received data is received, for example, whether it is received as electronic distribution or as printer output. Thus, with the development of technology, the MFP has improved its productivity and convenience.
JP-A-5-304575 Japanese Patent Laid-Open No. 2001-169032 JP 2006-203799 A

  However, in the past, it was only aimed at improving various performances of the MFP itself, such as improving copy productivity and making various functions such as duplex copying available, and used for printing proposed in the present invention. There is no description regarding a method for managing the originality of image data.

  Taking the BOX function as disclosed in Patent Document 3, for example, the data on the parent side is sent to the child side as it is at the time of registration, so that the data can be reused without further deterioration on the child side. Therefore, there is a problem in terms of management of original data. Digital data is very easy to replicate because it is originally data. For this reason, if the originality of the image data is not managed in some way, there is a risk that an inexhaustible copy will be made without the knowledge of the author.

  However, if data sharing is not performed efficiently because originality management is easy, productivity is sacrificed, and as a result, the value of the MFP as a device that transmits information is greatly reduced. . In view of such problems, the present invention provides an image processing apparatus capable of managing the originality of a file without sacrificing productivity.

  An image processing system according to the present invention is an image processing system that processes image data communicated between a communication source and a communication destination image processing apparatus connected via a network. Image writing means for printing data, storage means for storing image data and its accompanying information, external I / F means for transmitting and receiving image data and its accompanying data to an external device, and processing of image data from said storage means Output data output means, and the communication source image processing device communicates with the communication destination image processing device and outputs data to the storage means in parallel with the output. It has a control means for controlling whether or not to store.

  The image processing system according to the present invention further comprises selection means for selecting the data contents when data is stored in the communication destination storage means.

  In the image processing system according to the present invention, when the control unit stores data in the image processing apparatus, the color information of the data is changed according to the stored data.

  In the image processing system according to the present invention, when the control unit stores data in the image processing apparatus, the resolution of the data is changed according to the stored data.

  Further, in the image processing system according to the present invention, the control means sets the data to be accumulated in the image processing apparatus only as an incidental situation.

  Further, in the image processing system according to the present invention, the control means sets the data to be stored as the incidental status and the thumbnail in the image processing apparatus.

  In addition, the image processing system according to the present invention enables the image processing apparatus to search data stored in the communication source from the communication destination even from data other than images such as thumbnails and incidental conditions stored in the communication destination. It is characterized by.

  The image processing apparatus according to the present invention includes an image writing means for printing image data on transfer paper, a storage means for storing image data and its accompanying information, and an external device for transmitting and receiving image data and its accompanying data to and from an external device. / F means, data output means for processing and outputting the image data from the storage means, and communication with the image processing apparatus of the communication destination, and when outputting the data, the data is output to the storage means in parallel with the output. It has a control means for controlling whether or not data is stored.

  According to the present invention, by selecting the storage of the image data at the time of the connecting operation, the original image data of the transmission source not intended by the user is not duplicated from the transmission destination image processing apparatus, and the search function is used. It is possible to manage the originality of the image data of the transmission source and the transmission destination.

  First, FIG. 1 shows an embodiment of an image processing system using the present invention. In this figure, this system includes one image processing apparatus master machine A18 for performing a desired operation by a user and one or more (one in FIG. 1) image processing apparatus slave machines B19 that are connected to the image processing apparatus master machine A18. And a network 17 for connecting these image processing apparatuses.

  In this embodiment, an image processing apparatus applicable as the image processing apparatus master machine A18 and the image processing apparatus slave machine B19 constituting the system has a configuration shown in FIG. The image processing apparatus master machine A18 receives a desired operation (setting, etc.) when the user uses this system. Also, processing is executed for the received request, and if necessary, an instruction according to the request is given to the image processing apparatus slave device B19 which is the connection destination. Thus, it is called a master machine because it is a communication source that plays a commanding role in this system.

  The image processing apparatus slave unit B19 receives an instruction from the master unit A18 and executes a process according to the content. In this way, the communication destination that plays the role of receiving the instruction in this system is called a slave device.

  In this embodiment, the master machine A18 and the slave machine B19 have equivalent functions. Therefore, according to the user's request, the image processing apparatus master machine A18 in FIG. 1 can be the image processing apparatus slave machine B19, and conversely, the image processing apparatus slave machine B19 can also be the image processing apparatus master machine A18. obtain.

  FIG. 2 shows an example of an overall configuration diagram of the MFP according to the present invention. The reading device 1 includes a line sensor composed of a CCD (photoelectric conversion element), an A / D converter, and a drive circuit thereof, and digital images of 8 bits for each of RGB from the density information of the original obtained by scanning the set original. Generate and output data.

  The image data processing device 2 performs a process for unifying the digital image data output from the reading device 1 to a predetermined characteristic and outputs the processed digital image data. The characteristics to be unified are characteristics suitable for changing the output destination when image data is stored in the MFP and then reused.

  The bus control device 3 is a data bus control device that exchanges various data such as image data and control commands necessary in the digital image processing device, and also has a bridge function between a plurality of types of bus standards. In the present embodiment, the image data processing device 2, the image data processing device 4, and the CPU 6 are connected by a PCI-Express bus and the HDD by an ATA bus to form an ASIC.

  The image data processing device 4 applies image processing to an output destination designated by the user and outputs the digital image data whose characteristics predetermined by the image data processing device 2 are unified.

  The HDD 5 is a large-sized storage device for storing electronic data that is also used in a desktop personal computer, and mainly stores digital image data and accompanying information of the digital image data in the digital image processing apparatus. In this embodiment, an ATA bus-connected hard disk standardized by expanding IDE is used.

  The CPU 6 is a microprocessor that controls the entire control of the digital image processing apparatus. In this embodiment, an integrated CPU is used in which a + α function is added to a CPU core that has been widespread in recent years. This embodiment assumes RM11100 (registered trademark) of PMC, which uses a CPU integrated with a connection function with a general-purpose standard I / F and a bus connection function using a crossbar switch.

  The memory 7 stores data to be temporarily exchanged in order to absorb a speed difference when bridging between a plurality of types of bus standards and a processing speed difference between connected components themselves. It is a volatile memory that temporarily stores programs and intermediate processing data when controlling the apparatus.

  Since high-speed processing is required for the CPU, the system is started with a boot program stored in the ROM at normal startup, and thereafter, processing is performed by a program developed in the memory 7 that can be accessed at high speed. In this embodiment, a standardized DIMM used for a personal computer is used.

  When the plotter I / F device 28 receives digital image data composed of C (cyan), M (magenta), Y (yellow), and K (black) sent via the general-purpose standard I / F integrated with the CPU 6, the plotter I / F device 28 A bus bridge process for outputting to the dedicated I / F of the device 9 is performed.

The general-purpose standard I / F used in this embodiment is a PCI-Express bus.
When the plotter device 9 receives the digital image data composed of CMYK, the plotter device 9 outputs the received image data on the transfer paper using an electrophotographic process using a laser beam.

  S. B. Reference numeral 13 denotes one of chip sets used for a personal computer, which is a general-purpose electronic device called South Bridge. A bus bridge function often used in constructing a CPU system mainly including a PCI Express and an ISA bridge is formed as a general-purpose circuit. In this embodiment, the bus is bridged with a ROM.

  The ROM 14 is a memory for storing a program (including boot) when the CPU controls the digital image processing apparatus.

  The operation panel 10 is an interface between the digital image processing apparatus and the user. The operation panel 10 includes a display device using an LCD (Liquid Crystal Display) and an input device such as a key switch and a touch panel. The operation method is displayed on the display device, and the input from the user is detected by the input device. In the present embodiment, the CPU 6 is connected via a PCI-Express bus.

  The line I / F device 11 is a device for connecting a PCI-Express bus and a telephone line, and this apparatus enables the digital image processing apparatus to exchange various data via the telephone line.

  A facsimile (FAX) 15 is a normal FAX that exchanges image data with the digital image processing apparatus via a telephone line. The line I / F device 12 is a device that connects a PCI-Express bus and an external device. This device enables the digital image processing apparatus to exchange various data with the external device.

  In this embodiment, a network {Ethernet (registered trademark)} is used for the connection I / F. That is, this digital image processing apparatus is connected to the network via the line I / F apparatus 12.

  The PC 16 is a so-called personal computer, and a user can perform various controls and input / output of image data with respect to the digital image processing apparatus through application software and drivers installed in the personal computer. The above is the configuration of the MFP used in this embodiment.

  In the following, each operation of the MFP alone, which is a premise when describing the connection operation that is a feature of the present embodiment, will be described.

(Copy operation)
A user sets a document on the reading apparatus 1 and performs setting of a desired mode and input of copy start on the operation panel 10. The operation panel 10 converts the information input from the user into control command data inside the device and issues it.

  The issued control command data is notified to the CPU 36 via the PCI-Express bus. The CPU 36 executes a copy operation process program in accordance with the copy start control command data, and sequentially performs settings and operations necessary for the copy operation. The operation process is described below in order.

  The RGB 8-bit digital image data obtained by scanning the document with the reading device 1 is unified into predetermined characteristics by the image data processing device 2 and sent to the bus control device 3.

  When receiving the RGB image data from the image data processing device 2, the bus control device 3 accumulates it in the memory 7 via the CPU 6. Next, the RGB image data stored in the memory 7 is sent to the image data processing device B4 via the CPU 6 and the bus control device 3.

  The image data processing device B4 converts the received RGB image data into CMYK image data for plotter output and outputs it. When the bus control device 3 receives the CMYK image data from the image data processing device B4, the bus control device 3 stores it in the memory 7 via the CPU 6.

  Next, the CMYK image data stored in the memory 7 is sent to the plotter device 9 via the CPU 6 and the plotter I / F device 28. The plotter device 9 outputs the received CMYK image data to transfer paper, and a copy of the document is generated.

(FAX transmission operation)
The user sets a document on the reading apparatus 1 and performs setting of a desired mode and the like and input of FAX start on the operation panel 10. The operation panel 10 converts the information input from the user into control command data inside the device and issues it.

  The issued control command data is notified to the CPU 6 via the PCI-Express bus. The CPU 6 executes a FAX transmission operation process program in accordance with control command data for starting FAX transmission, and sequentially performs settings and operations necessary for the FAX transmission operation. The operation process is described below in order.

  The RGB 8-bit digital image data obtained by scanning the document with the reading device 1 is unified into predetermined characteristics by the image data processing device 2 and sent to the bus control device 3.

  When receiving the RGB image data from the image data processing device 2, the bus control device 3 accumulates it in the memory 7 via the CPU 6. Next, the RGB image data stored in the memory 7 is sent to the image data processing device 4 via the CPU 6 and the bus control device 3.

  The image data processing device 4 converts the received RGB image data into monochrome binary image data for FAX transmission and outputs it. When the bus control device 3 receives the monochrome binary image data from the image data processing device 4, it stores it in the memory 7 via the CPU 6.

  Next, the monochrome binary image data stored in the memory 7 is sent to the line I / F device 11 via the CPU 6. The line I / F device 11 transmits the received monochrome binary image data to the FAX 15 connected via the line.

(Scanner delivery operation)
A user sets a document on the reading device 1 and performs setting of a desired mode and the like and input of scanner distribution start on the operation panel 10. The operation panel 10 converts the information input from the user into control command data inside the device and issues it.

  The issued control command data is notified to the CPU 6 via the PCI-Express bus. The CPU 6 executes a scanner distribution operation process program in accordance with the scanner distribution start control command data, and the scanner sequentially performs settings and operations necessary for the distribution operation. The operation process is described below in order.

  The RGB 8-bit digital image data obtained by scanning the document with the reading device 1 is unified into predetermined characteristics by the image data processing device 2 and sent to the bus control device 3. When receiving the RGB image data from the image data processing device 2, the bus control device 3 accumulates it in the memory 7 via the CPU 6. Next, the RGB image data stored in the memory 7 is sent to the image data processing device 4 via the CPU 6 and the bus control device 3.

  The image data processing device 4 converts the received RGB image data into image data for scanner distribution and outputs it. (RGB multivalue, grayscale, monochrome binary, etc.)

  When receiving the image data from the image data processing device 4, the bus control device 3 accumulates it in the memory 7 via the CPU 6. Next, the image data stored in the memory 7 is sent to the line I / F device 12 via the CPU 6. The line I / F device 12 transmits the received image data to the PC 16 connected via the network.

  The image processing apparatus 4 is an image processing apparatus having the same configuration as the image processing apparatus 2 having the configuration shown in the left side of FIG. 2 (inside the apparatus) described above, and various controls between the image processing apparatuses necessary for the connection operation of this system. Input / output of incidental information and image data.

  Hereinafter, the “concatenated copy operation” in this system will be described. In the description, the following numbering is used to clarify whether the name of each part is the master machine A18 side or the slave machine B19 side. That is, in the case of the reading device 2 on the master device A18 side, the reading device A1802, and in the case of the line I / F device 12 on the slave device B19 side, the external I / F device B1912.

First, the user sets a document on the reading device A 1801 by using the master machine A 18, and inputs a setting of a desired mode and the like and an input of linked copy start to the operation display device A 1810.
The operation display device A 1810 converts information input from the user into control command data inside the device and issues it.

  The issued control command data is notified to the CPU A 1806 via the PCI-Express bus. The CPU A 1806 executes a linked copy operation process program in accordance with linked copy start control command data, and sequentially performs settings and operations necessary for the linked copy operation. The operation process is described below in order.

  The RGB 8-bit digital image data obtained by scanning the original with the reading device A 1801 is unified into predetermined characteristics by the image data processing device A 1802 and sent to the bus control device A 1803.

When the bus control device A1803 receives the RGB image data from the image data processing device A1802, the bus control device A1803 stores it in the memory A1807 via the CPUA1806.
At that time, information including the desired operation performed by the user, the acquired model, date, and the like (accompanying information) is also stored together.

  From here, the operation branches to the operation on the master device A18 side and the connection operation on the slave device B19 side, but the operation on the master device A18 side is the same as that in the single function operation, and the description is omitted. One or more slave machines B19 can be connected, but in the present embodiment, one slave machine B19 is used. This is because even if there are two or more units, the operation of the slave unit B19 is equivalent.

  Hereinafter, the second embodiment will be described. That is, image data obtained by scanning a document with the single function of the master machine A18 is distributed by scanner, stored and stored in the image processing apparatus, and then stored and stored by the connecting function of the master machine A18 and the slave machine B19. A method for managing the originality of communication source data when using data as a concatenation operation will be described.

  First, the operation of a single function that distributes image data obtained by scanning a document by scanner and stores and saves it in the image processing apparatus will be described. The single function of the master machine A18 is “scanner distribution operation + storage / storage operation in HDD”.

  The user sets a document on the reading device A 1801 using the master machine A 18, and inputs a setting of a desired mode and the like and an input of scanner distribution start to the operation display device A 1810.

  The operation display device A 1810 converts information input from the user into control command data inside the device and issues it. The issued control command data is notified to the CPU A 1806 via the PCI-Express bus.

  The CPU A 1806 executes a scanner delivery operation process program in accordance with the scanner delivery start control command data, and sequentially performs settings and operations necessary for the scanner delivery operation. The operation process is described below in order.

  The RGB 8-bit digital image data obtained by scanning the original with the reading device A 1801 is unified into predetermined characteristics by the image data processing device A 1802 and sent to the bus control device A 1803.

  FIG. 3 shows a processing block diagram of the image data processing apparatus A 1802, which will be described in order. The γ conversion A 1820 unifies the brightness of the RGB image data received from the reading device A 1801 to a predetermined characteristic. In this embodiment, the lightness is converted into a linear characteristic.

  Filter processing A1821 unifies the sharpness of RGB image data to a predetermined characteristic. In the present embodiment, when the reference chart is scanned, conversion is performed so that the MTF characteristic value determined in advance for each number of lines is obtained.

  The color conversion A 1822 unifies the colors of the RGB image data with predetermined characteristics. In this embodiment, the color space is converted so as to be an Adobe-RGB color space defined by Adobe.

  The scaling process A1813 unifies the size (resolution) of the RGB image data to a predetermined characteristic. In this embodiment, the size (resolution) is converted to 600 dpi.

  When the bus control device A1803 receives the RGB image data from the image data processing device A1802, the bus control device A1803 stores it in the memory A1807 via the CPUA1806.

  The RGB image data stored in the memory A 1807 is transmitted to the HDD A 1805 via the CPU A 1806 and the bus control device 1123, and stored / stored in the HDD A 1805. At that time, arbitrary operations performed by the user and information (accompanying information) including the acquired model and date are also stored and stored together.

Thereafter, as described above, the RGB image data in the memory A 1807 is output to the external I / F device A 1811 via the image data processing device A 1804, and scanner distribution is performed.
FIG. 4 shows a processing block diagram of the image data processing apparatus A 1814, and the operation at this time will be described in order.

  The filter processing A1830 corrects the sharpness of the RGB image data so that the reproducibility when the scanner is distributed is improved. Specifically, sharpening / smoothing processing is performed according to desired mode information. For example, in the character mode, a sharpening process is performed to make the character clear / clear, and in the photo mode, a smoothing process is performed to smoothly express gradation.

  When color conversion A1831 receives RGB 8-bit data, it converts it into a designated color space. In this embodiment, each color is converted into 8 bits in the sRGB color space, which is common in scanner distribution.

  The scaling process A 1832 converts the size (resolution) of the sRGB image data into the size (resolution) transmitted / received by the designated scanner delivery. In this embodiment, the main scanning is converted to 200 dpi × sub-scanning: 200 dpi.

  In gradation processing A1833, gradation number conversion processing is performed according to the gradation processing capability transmitted and received by the designated scanner distribution. In this embodiment, assuming that 160,000 colors of 8 bits for each RGB are designated, the gradation processing is not particularly performed.

  Next, an operation for using the image data stored / stored in the HDDA 1805 as a connection operation will be described. The connection function between the master machine A18 and the slave machine B19 is “to manage the originality of communication source data when using the stored and stored image data as a connection operation”.

  For the image data stored / stored in the HDD A 1805 when the scanner delivery operation is performed earlier, the user inputs to the operation display device A 1810 the connection copy start input and the subsequent data management information.

  FIG. 5 shows a simple screen example of a selection screen related to data management information. The operation display device A 1810 converts information input from the user into control command data inside the device and issues it. The issued control command data is notified to the CPU A 1806 via the PCI-Express bus.

The CPU A 1806 executes a linked copy operation process program in accordance with the linked copy start control command data, and sequentially performs settings and operations necessary for the linked copy operation.
The operation process is described below in order.

  The bus control device A 1803 outputs the RGB image data and accompanying information stored in the HDD A 1805 to the memory A 1807 via the CPU.

  The RGB image data, supplementary information, and data management information output to the memory A 1807 are converted into CMYK image data for plotter output in accordance with the supplementary information and data management information by the image data processing device A 1804 via the CPU A 1806. After the conversion, the data is transmitted to the slave device B19 that is connected via the network. In addition, the description regarding data management information is demonstrated in the 2nd-5th embodiment mentioned later.

  After receiving the CMYK image data, the external I / F device B 1912 of the slave device B 19 stores the data in the memory B 1907 via the CPU B 1906. Next, the CMYK image data stored in the memory B 1907 is sent to the plotter device B 1909 via the CPU B 1906 and the plotter I / F device B 1908.

  The plotter device B 1909 outputs the received CMYK image data to transfer paper, and a copy of the document is generated. Here, according to the data management information sent from the master machine A 18, the data stored in the memory B 1907 is deleted as it is or stored in the HDD B 1905. As a result, the originality of the data stored and stored in the image processing apparatus can be managed by deleting the data or converting it into desired data after the data is output.

  In addition, for the data stored and stored in the image processing apparatus, an output destination different from that at the time of input (in this embodiment, a case where an application is different is shown. Input: scanner distribution, output: linked copy) is desired. In this case, there is an advantage that the output destination can be changed without any change in image quality as compared with the normal operation (operation when the output destination is designated from the beginning).

  In the present embodiment, the operation is performed on the image data once stored, but the effect is the same even when the output and storage are performed in parallel in the master machine A18.

  A third embodiment will be described. That is, image data obtained by scanning a document by the single function of the master machine A18 is stored and stored in the image processing apparatus, and then the image data stored and stored by the connecting function of the master machine A18 and the slave machine B19 is reused. The operation regarding the handling of the color data is described.

  First, a case where image data obtained by scanning a document with the single function of the master machine A18 is stored and stored in the image processing apparatus will be described. In the first embodiment, when a single function is used, the user can set a color-related mode.

  For example, in a copy operation, a color mode that reproduces a color document in color, a monochrome mode that reproduces in black and white, a single color mode that reproduces in a single color such as cyan or magenta, and other color conversion modes that convert a specified color to another color Etc.

  In the stage where image data is stored and saved by the single function of the master machine A18, the color conversion A1822 of the image data processing apparatus A1802 determines the color of the RGB image data in advance, regardless of the color mode setting specified by the user. The characteristics are unified and stored in the HDDA 1805.

  In the present embodiment, the color space is converted to the Adobe-RGB color space defined by Adobe. The color conversion method employs a known three-dimensional lookup method.

  Next, use of image data stored and stored by the connecting function of the master machine A18 and the slave B19 will be described. In the first embodiment, the user can set the color mode even when using the link function. For example, even in linked copy operations, color mode that reproduces a color document in color, monochrome mode that reproduces in black and white, single color mode that reproduces in a single color such as cyan or magenta, and other color conversion that converts a specified color to another color There are modes.

  When using the image data stored and saved by the connecting function of the master machine A18 and the slave machine B19, the data management information on the color specified by the user on the selection screen shown in FIG. In color conversion A1851 of processing apparatus A1804, according to data management information (color mode information), conversion is performed from Adobe-RGB: 8-bit image data to a designated color. As a conversion method in this embodiment, a known three-dimensional lookup method is adopted.

  As a result, it is possible to change the mode setting regarding the color at the time of input of the data stored and stored in the image processing apparatus when the data is output to the slave unit B19 again. The originality of the stored image data can be managed.

  As a specific example, the full color mode is set by copying with a single function of the master machine A18, and the image data is stored and stored in the image processing apparatus, and then stored by the connecting function of the master machine A18 and the slave machine B19. -Saved image data can be reused in monochrome mode as a linked copy.

  Next, a fourth embodiment will be described. That is, image data obtained by scanning a document by the single function of the master machine A18 is stored and stored in the image processing apparatus, and then the image data stored and stored by the connecting function of the master machine A18 and the slave machine B19 is used. In this case, the operation regarding the handling of resolution will be described.

  First, a case where image data obtained by scanning a document with the single function of the master machine A18 is stored and stored in the image processing apparatus will be described. In the first embodiment, when a single function is used, the user can set a mode for zooming. For example, there are modes such as scaling for enlargement / reduction in the copy operation and resolution designation such as 600, 400, 300, 200 dpi in the scanner operation.

  At the stage of storing and saving image data by the single function of the master machine A18, the scaling process A1833 unifies the size (resolution) of the RGB image data to a predetermined characteristic regardless of the resolution setting specified by the user. In this embodiment, the size (resolution) is converted to 600 dpi.

  Next, the use of image data stored and stored by the connecting function of the master machine A18 and the slave machine B19 will be described. In the first embodiment, the user can set the mode for zooming even when using the connection function. For example, there is a scaling mode such as enlargement / reduction in the linked copy operation.

  When using the image data stored and saved by the connecting function of the master machine A18 and the slave machine B19, the master machine A18 uses the data management information regarding the resolution specified by the user on the selection screen as shown in FIG. 5 together with the image data. Processing is performed in a scaling process A1852 of the image data processing apparatus A1804.

  As a result, it is possible to change the mode setting related to the resolution at the time of inputting the data stored and stored in the image processing apparatus when the data is output again to the slave machine B19, and further, the master machine A18. It is possible to manage the originality of the image data stored in. As a specific example, the image data stored and saved by the connecting function of the master machine A18 and the slave machine B19 can be reused at a reduced resolution as a linked copy.

  Next, a fourth embodiment will be described. That is, image data obtained by scanning a document by the single function of the master machine A18 is stored and stored in the image processing apparatus, and then the image data stored and stored by the connecting function of the master machine A18 and the slave machine B19 is used. In this case, we will explain how to handle information.

  First, an image obtained by scanning a document by a single function of the master machine A18 is accumulated and stored in the image processing apparatus.

  Next, when using the image data stored and saved by the connecting function of the master machine A18 and the slave machine B19, the image data is processed by the image data processing device A1904 of the master machine A18 according to the data management information, and the slave machine B19. The image data is transmitted with data management information, supplementary information, and thumbnail image data.

  After performing the predetermined processing, the slave unit B19 deletes the image data from the memory B1907, and stores the auxiliary information and thumbnail image data in the HDDB 1905 through the CPUB 1906. The supplementary information may include information that can specify image data to some extent, for example, an operation requested by the user, date, data name, communication destination information, and the like.

  As a result, it is possible to leave the information (history) of the data stored and stored in the image processing apparatus when it is re-outputted to the slave unit B19, and the originality of the image data stored in the master unit A18. Can be managed.

  Next, a fifth embodiment will be described. That is, image data obtained by scanning a document by the single function of the master machine A18 is stored and stored in the image processing apparatus, and then the image data stored and stored by the connecting function of the master machine A18 and the slave machine B19 is used. In this case, we will explain how to handle information.

  The present embodiment relates to the above-described embodiment and relates to handling of image information stored in the slave device B19. The data is stored in the HDD B1905 of the slave machine B19, but this data can be retrieved by the operation display device B1910 of the slave machine B19. FIG. 6 shows a specific example of a simple display screen.

  By searching the transmission information destination and this display screen to check the presence or absence of information, or to extract the information itself, the image data can be used without leaving image data in the slave unit B19. Is possible.

  As a result, the image data can be stored in one location, and the originality of the data can be managed. Note that the incidental information is also stored and stored in the master machine A18. Therefore, by searching the master machine A18 using the additional information saved and stored at the time of transmission from the slave machine B19 as a search key, it is stored in the slave machine B19. The image data stored in the master machine A18 can be called from the incidental information and reused.

  Further, in this case, by preventing the reused image data from remaining in the slave unit, the image data can be stored in one place, and the originality of the image data can be managed.

It is a figure which shows the structure of the image processing system of embodiment of this invention. It is a figure which shows the structure of the image processing apparatus in embodiment of this invention. It is a figure which shows the structure of the image data processing apparatus 2 of FIG. It is a figure which shows the structure of the image data processing apparatus 4 of FIG. It is a figure which shows the example of a display of the selection screen for performing the data management of the image processing apparatus in embodiment of this invention. It is a figure which shows the example of a screen display which concerns on the search of the image processing apparatus in embodiment of this invention.

Explanation of symbols

A18 Master image processing device B19 Slave image processing device 17 Network 1 Reading device 2, 4 Image data processing device 3 Bus control device 5 HDD
6 CPU
7 Memory 8 Plotter I / F device 9 Plotter device 10 Operation panel 11 Line I / F device 12 External I / F device 13 B. (South Bridge)
14 ROM
15 FAX
16 PC
30 γ conversion 31, 50 Filter conversion 32, 51 Color conversion 33, 52 Scaling processing 53 Gradation processing

Claims (9)

In an image processing system for processing image data communicated between a communication source and a communication destination image processing apparatus connected via a network,
The image processing apparatus includes an image writing unit that prints image data on a transfer sheet;
Storage means for accumulating image data and associated information;
An external I / F means for transmitting / receiving image data and its associated data to / from an external device;
Data output means for processing and outputting image data from the storage means,
The communication source image processing apparatus has a control means for controlling whether to store data in the storage means in parallel with the output when communicating with the communication destination image processing apparatus and outputting data. An image processing system characterized by that.   The image processing system according to claim 1, wherein the communication source image processing apparatus includes a selection unit that selects data contents when storing data in the communication destination storage unit.   The image processing system according to claim 2, wherein the control unit changes color information of the data according to the accumulated data.   4. The image processing system according to claim 2, wherein the control unit changes the resolution of the data according to the accumulated data.   5. The image processing system according to claim 4, wherein the control means sets the accumulated data as an incidental situation.   5. The image processing system according to claim 4, wherein the control means uses thumbnails as data to be stored.   5. The image processing system according to claim 4, wherein the control means sets the accumulated data as thumbnails and incidental statuses.   8. The communication destination image processing apparatus according to claim 5, further comprising means for searching image data stored in the communication source image processing apparatus with reference to the stored data. The image processing system according to item 1. Image writing means for printing image data on transfer paper;
Storage means for accumulating image data and associated information;
An external I / F means for transmitting / receiving image data and its associated data to / from an external device;
Data output means for processing and outputting image data from the storage means;
An image processing apparatus comprising control means for controlling whether or not data is stored in a storage means in parallel with output when communicating with an image processing apparatus as a communication destination and outputting data.

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