JP2003208281A - Image forming device associating with other device through network - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an image forming device capable of transferring a coordinate parameter for designating a picture layout through a network to a device used by a user, and executing prescribed processing based on a function option set by the user received through the network. <P>SOLUTION: This image forming device is provided with a picture generating means for generating picture information displaying a plurality of function options based on option information indicating a plurality of function options settable for prescribed processing, transferring means for transferring the option information to the other device, and a processing control means for controlling the prescribed processing by using hardware resources for executing the prescribed processing at the time of receiving a setting parameter indicating the function option set by the user from the plurality of function options displayed by using the option information by the device from the above mentioned device. <P>COPYRIGHT: (C)2003,JPO

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an image processing device, and more particularly, to image data input by a user,
Image input / output devices that input and output images such as copies and faxes that are connected via a network, image output devices that output images such as printers, image storage devices such as file servers and various databases, or image processing. An image forming apparatus that cooperates with each other via a network such as an image processing apparatus and an image input / output apparatus that transmits to an image processing apparatus that performs the image forming apparatus. Further, an image forming method for performing processing in such an apparatus is provided.

An image processing apparatus and an image input / output apparatus which output an image based on image data received from another image processing apparatus or image input / output apparatus, execute predetermined image processing, or accumulate the image data. The present invention relates to an image forming apparatus that cooperates with each other via a network such as. Further, an image forming method for performing processing in such an apparatus is provided.

[0003]

2. Description of the Related Art As a conventional technique for performing processing relating to image data to an image processing apparatus or an image input / output apparatus connected via a network, for example, Japanese Patent Laid-Open No. 2000-6496
The invention disclosed in the publication is known. The present invention provides an image processing apparatus that can be connected to an information output apparatus via a network and that can prevent the output image quality from being impaired when output is performed by all devices on the network. For that purpose, the correction data of the image processing is acquired via the network, the image correction optimum for the output is performed, and the data is output to the device connected to the network.

[0004]

In an image processing apparatus or an image input apparatus connectable to an image input / output apparatus via such a network, when outputting by any apparatus on the network, There is a problem in that the user's operation and image processing are different because the functions are different from each other and have unique features.

For example, if there is a high-performance copier with a sorter or stapler at the network destination and another model or copier with only a single function is at hand, the "Scan To Print" function is used to connect to the network destination. Can be output to the copy machine, but at that time, the finisher or stapler at the network destination cannot be used in the same manner as in normal use.

Further, in image input for the purpose of accumulating images in another server or database instead of paper output, or for secondary use such as OCR, it is necessary to improve accuracy in order to achieve each purpose. There is. To improve the accuracy in this way, it is necessary to change the image processing. Furthermore, it is necessary to prepare a user interface for setting and inputting information necessary for the purpose. It is impossible to prepare a user interface that meets all of these needs in the image input device, and it is difficult to customize the interface to meet the needs.

The present invention has been made in view of such a background, and an object thereof is to form an image in which the user interface can be unified regardless of which device on the network is used when the device on the network is used. An apparatus and an image forming method are provided.

Another object is to easily meet various demands of image input / output without changing image processing and preparing a user interface for setting and inputting necessary information. An image forming apparatus and an image forming method capable of performing the same are provided.

[0009]

In order to solve the above-mentioned problems, according to the present invention, as described in claim 1, based on option information indicating a plurality of function options that can be set for a predetermined process, Screen generation means for generating screen information for displaying the plurality of function options; transfer means for transferring the option information in response to a request from a device used by the user connected through a network; Hardware for performing the predetermined process based on the setting parameter when the setting parameter indicating the function option set by the user is received from the plurality of function options displayed by the device using the option information from the device. And a processing control means for controlling the predetermined processing by utilizing resources.

In such an image forming apparatus, since the above-mentioned option information is transferred to the apparatus used by the user via the network, the user uses the screen of the image forming apparatus to obtain the desired function option. Can be set. The user can also cause the image forming apparatus to perform a predetermined process from the apparatus. Therefore, the apparatus does not need to be provided with a unit for providing a screen similar to that of the image forming apparatus in advance in order to use the processing in the image forming apparatus. Further, it is not necessary to equip the apparatus with a predetermined process provided by the image forming apparatus.

Further, according to the present invention, as described in claim 2, the predetermined process is a process relating to image formation,
An application having the image generation control means and the processing control means, managing the hardware resources, and responding to a use request from the application,
It can be configured to have a control service that controls utilization to the hardware resource, and an operating system that controls the application and the control service.

Such an image forming apparatus has a function as a computer apparatus and can directly control hardware resources used for image formation.

Further, according to the present invention, as described in claim 3, in response to a request from the device for confirming whether or not the predetermined processing is possible, the image forming device is connected on the network. It is configured to have a response unit that responds with device identification information including a device address to specify and a device name.

In such an image forming apparatus, it is possible to notify the apparatus connected via the network that processing is possible.

According to a fourth aspect of the present invention, the plurality of input function options are used as the screen generation means on the basis of input option information indicating a plurality of input function options related to image input processing. And an image processing screen information for displaying the plurality of image processing function options based on image processing option information indicating a plurality of image processing function options related to image processing. At least one of an image processing screen generating unit for generating the output screen information for displaying the plurality of output function options based on the output option information indicating the plurality of output function options for the image output processing. Is configured to have.

In such an image forming apparatus, an input screen,
At least one of the image processing screen and the output screen can be displayed on the display unit, and at least one of the input screen, the image processing screen and the output screen can be displayed by the transfer means.
Optional information regarding one can be transferred to a device connected via a network.

Further, according to the present invention, as the processing control means, as the processing control means, an input control means for controlling input processing of an image to generate input image data, and an image for the input image data are provided. At least one of image processing control means for generating image output data for processing and outputting, and output control means for controlling output processing for forming and outputting an image on a medium based on the image output data is provided. Is configured as follows.

In such an image forming apparatus, at least one of input processing, image processing and output processing can be performed in response to a request from an apparatus connected via a network.

Further, according to the present invention, as described in claim 6, the input control means is configured to control the scanner as the hardware resource for performing the input processing. Further, according to the present invention, as described in claim 7, the output control means is configured to control a plotter as the hardware resource for performing the output processing.

In such an image forming apparatus, input processing can be performed using a scanner and output processing can be performed using a plotter.

According to the present invention, as the transfer means, as the transfer means, input screen transfer means for transferring the input option information relating to the input processing designated by the request to the device, and the image processing. Image processing option transfer information for transferring image processing option information to the device, and output screen transfer device for transferring output option information related to output processing to the device.

In such an image forming apparatus, it is possible to provide input option information for an input screen, image processing option information, or output option information in response to a request from an apparatus connected via a network. Therefore, the apparatus can display the input screen, the image processing screen, or the output screen of the image forming apparatus according to the request.

Further, according to the present invention, as described in claim 9, based on the first option information indicating a plurality of first function options that can be set for a predetermined process, on the basis of the option information indicating A screen generating means for generating first screen information for displaying the plurality of first function options, and a plurality of second functions processable by the device transmitted from a device selected by a user connected through a network Replacement means for replacing the first screen information with second screen information displaying the plurality of second function options based on second option information indicating an option; and the plurality of the plurality of display means based on the second screen information. From the second function option, send to the device a setting parameter indicating the one or more second function options set by the user. And by configured to have a processing requesting means for requesting the predetermined processing to the device.

In such an image forming apparatus, the screen generating means for generating the first coordinate parameter for displaying the function option of the image forming apparatus itself is provided from the apparatus selected by the user connected through the network. Further, the screen display can be realized by using the second coordinate parameter for displaying the function option of the device. Further, since the setting parameter indicating the second function option set by the user is transmitted to the device, the device can be requested to perform the processing. For example, even if the function of the image forming apparatus is lower than the function of the apparatus selected by the user connected via the network, the high function of the apparatus can be used from the image forming apparatus. Become.

According to a tenth aspect of the present invention, as the screen generating means, based on the input option information indicating a plurality of input function options relating to the image input processing by the user, Input screen generation means for generating input screen information for displaying the input function options as the screen information, and the plurality of image processing functions based on the image processing option information indicating the plurality of image processing function options related to image processing by the user. Based on image processing screen generation means for generating image processing screen information for displaying options as the screen information, and output option information indicating a plurality of output function options relating to image output processing by the user, the plurality of output function options The output screen information that displays is generated as the above screen information. Yes As configured at least one of the screen generating means.

In such an image forming apparatus, it is possible to display a screen of an apparatus connected via a network regarding processing desired by the user.

Further, according to the present invention, as the processing requesting means, the user sets, as the processing requesting means, from a plurality of input function options which can be set for the input processing by the apparatus. Input processing requesting means for requesting the device to perform the input processing by transmitting an input setting parameter indicating one or more input function options to the device, and a plurality of input processing parameters that can be set for the image processing by the device. Image processing requesting means for requesting the image processing to the apparatus by transmitting to the apparatus image processing setting parameters indicating one or more image processing function options set by the user from the image processing function options; One or more set by the user from a plurality of output function options that can be set for the output processing by the device. By sending an output setting parameter indicating an output function option to the apparatus configured to have at least one of the output processing request means for requesting the output processing to the device.

In such an image forming apparatus, the processing desired by the user can be executed by the apparatus connected via the network.

Further, as means for solving the above-mentioned problems, the present invention can use the processing in the above-mentioned image forming apparatus as an image forming method.

[0030]

BEST MODE FOR CARRYING OUT THE INVENTION Embodiments of the present invention will be described below with reference to the drawings. [First Embodiment] An image forming apparatus according to a first embodiment of the present invention that fuses various image forming functions (hereinafter referred to as a fusion machine).
Has a functional configuration as shown in FIG. 1, for example. Figure 1
FIG. 1 is a block diagram showing a functional configuration of a compound machine that combines various image forming functions according to a first embodiment of the present invention.

In FIG. 1, a compound machine 1200 is a plotter 1 which is a hardware resource for performing printer processing.
321, a scanner 1324 that is a hardware resource for performing a scanner process, and other hardware resources 1203, and the platform 1
The software 1210 includes a 220 and an application 1230, and an activation unit 1240.

The start-up unit 1240 is first executed when the power of the compound machine 1200 is turned on, and the platform 122
0 or the application 1230 is activated.

API (Application Program Interfac
e) 1205 provides the interface between the application 1230 and the platform 1220. The platform 1220 interprets a processing request from the application 1230 notified via the API 1205 and manages one or a plurality of hardware resources and a control service 1250 described below that generates a hardware resource acquisition request. , A system resource manager (SRM) that arbitrates acquisition requests from the control service 1250.
r) 1223) and the OS 1221.

The control service 1250 is formed by a plurality of service modules, and specifically,
SCS (System Control Service) 1222 and ECS
((Engine Control Service) 1224 and MCS (Memo
ry Control Service) 1225 and OCS (Operation
panel Control Service) 1226 and FCS (FAX Con
Control Service) 1227 and NCS (Network Control)
Service) 1228 and IMH (Imaging Memory Handle)
r) 1229.

The OS 1221 is an operating system such as UNIX (registered trademark), and executes each software of the platform 1220 and the application 1230 as processes in parallel. By using the open source UNIX (registered trademark), the safety of the program can be secured, the network can be supported, and the source code can be easily obtained. Further, royalties of OS and TCP / IP are not required, and outsourcing becomes easy.

The SRM 1223 controls the system and manages resources together with the SCS 1222. The SRM 1223 is an engine unit such as a scanner or plotter, a memory, an HDD file, a host I / O (Centro I / F,
Network I / F, IEEE1394 I / F, RS2
32C I / F, etc.) performs arbitration according to a request from an upper layer that uses a hardware resource such as 32 CI / F, and controls execution.

Specifically, the SRM 1223 determines whether the requested hardware resource is available (whether it is not used by another request), and if it is available, the requested hardware resource is available. Tell upper layers that wear resources are available. In addition, hardware resource utilization scheduling may be performed in response to a request from an upper layer, and the request content (for example, paper conveyance and image forming operation by the printer engine, memory reservation, file generation, etc.) may be directly executed. .

The SCS 1222 manages the application (function 1), controls the operation unit (function 2), displays the system screen (job list screen, counter display screen, etc.) (function 3), L
It performs a plurality of functions such as ED display (function 4), resource management (function 5), and interrupt application control (function 6). Specifically, in the application management (function 1), registration of the application,
Perform the process of notifying other applications of the information. In the operation unit control (function 2), exclusive control of the operation unit use right of the application is performed. In the system screen display (function 3), a warning screen corresponding to the state of the engine unit is displayed according to the request content from the application having the operation unit usage right. LE
In the D display (function 4), display control of system LEDs such as a warning LED and an application key is performed. The resource management (function 5) provides a service for exclusive control of engine resources (scanner, staple, etc.) that must be excluded when the application (ECS) executes a job. In the interrupt application control (function 6),
Performs control and services to prioritize specific applications.

The ECS 1224 has a plotter 1321 and
Scanner 1324 and other hardware resources 12
It controls the engine unit such as 03, and performs image reading and printing operation, status notification, jam recovery, and the like.

The MCS 1225 performs memory control, and specifically, performs acquisition and release of an image memory, use of a hard disk device (HD), compression and expansion of image data, and the like.

The OCS 1226 is a module for controlling the operation panel which is a means for transmitting information between the operator and the main body control, and is a process for notifying the main body control of an operator's key operation event, and a library function for each application to construct a GUI. Is provided, processing for managing the constructed GUI information for each application, display reflection processing on the operation panel, and the like are performed.

The FCS 1227 is used for facsimile transmission / reception from each application layer of the system controller using the PSTN / ISDN network, registration / citation of various facsimile data managed by BKM (backup SRAM), facsimile reading, facsimile reception printing, fusion transmission / reception. An API 1205 for performing the above is provided.

The NCS 1228 is a group of modules for providing services that can be commonly used for applications that require network I / O. The NCS 1228 distributes data received by each protocol from the network side to each application, and Mediates when data is transmitted from the network to the network side. The NCS 1228 is, for example, at least an ht for performing communication with a device connected via a network.
tpd (Hypertext Transfer Protocol Daemon) 2,
FTP (File Transfer Protocol) for transferring files related to the image input / output interface 3
Have and.

The IMH 1229 maps image data from the virtual memory area to the physical memory area. In response to the activation of the process, a system call is performed to map the virtual memory area for the process, and release the mapped virtual memory area at the end of the process.

Application 1230 includes page description language (PDL), PCL and postscript (PDL).
A printer application 1211, which is a printer application having S), a copy application 1212 which is a copying application, a fax application 1213 which is a facsimile application, a scanner application 1214 which is a scanner application, and a net file application. A certain net file application 1215, an image input / output application 1216 that is an application that controls image input / output, and a transfer application 1217 that transfers an image input / output interface file.
And a document list application 1 that provides a list of managed documents
217 and. Each application 1211-12
Since 17 can operate and execute using each process on the platform 1220, the main part thereof is a screen display control program that performs screen control, key operation control, job generation, and the like. Note that a new application can be installed via the network via the network connected by the NCS 1228. Further, each application can be added or deleted for each application.

As described above, the multi-functional apparatus 1200 centrally processes the processing commonly required by each application on the platform 1220.

Next, the hardware configuration of the compound machine 1200 will be described. FIG. 2 is a block diagram of the compound machine 1200 shown in FIG.
FIG. 3 is a block diagram showing the hardware configuration of the above. As shown in FIG. 2, the multi-function peripheral 1200 includes an operation panel 1310 and a USB (Universal Serial Bus) 133.
0, IEEE13941340, plotter 1321, scanner 1324, and ASIC130 of controller 1300.
1 and PCI (Peripheral Component Interconnect)
It is configured to be connected by a bus 1309 or the like.

The controller 1300 has the ASIC 130.
1 to MEM-C1302, HD (Hard Disk) 1303
Etc. are connected and this ASIC1301 and CP
It is connected to U1304 via the NB1305 of the CPU chip set. In this way, the reason for connecting via the NB 1305 is that the interface of the CPU 1304 itself is not open to the public.

Here, the ASIC 1301 and the NB 13
05 is not simply connected via PCI, but is connected via AGP 1308. The reason for making the connection via the AGP 1308 is as follows.
This fusion machine 1200 is the platform 1 shown in FIG.
This is because, in order to control the execution of a plurality of processes forming the 220 and the application 1230, if these are connected by a low-speed PCI, the performance will decrease.

The CPU 1304 controls the compound machine 1200 as a whole, and specifically, the OS 1221.
SCS 122 forming platform 1220 on
2, SRM1223, ECS1224, MCS122
5, OCS1226, FCS1227, NCS122
8, IMH 1229 is started and executed as a process, respectively, and a printer application 1211, a copy application 1212 that forms an application 1230,
Fax application 1213, scanner application 1214,
Net file application 1215, image input / output application 12
16 and the transfer application 1217 are activated and executed. Further, the OS 1221 is used by the scanner 1324 and the plotter 13.
21, and controls other hardware resources such as the hardware resource 1203.

The OS 1221 of the image forming apparatus 1200 is
In this way, in order to directly control each hardware resource used for image processing, a personal computer (P
It is different from operating systems such as C).
This is because the PC can usually control the image forming apparatus such as the scanner or the printer connected thereto, but cannot control the hardware resources in the image forming apparatus.

The NB 1305 has a CPU 1304 and a MEM.
-P1306, SB1307, is a bridge for connecting the ASIC1301, MEM-P1306,
A system memory used as a drawing memory or the like of the multi-function peripheral. The SB 1307 is an NB 1305, a ROM, and a PC.
It is a bridge for connecting I devices and peripheral devices. The MEM-C1302 is a local memory used as a copy image buffer and a code buffer,
The ASIC 1301 is an IC for image processing applications having a hardware element for image processing.

The HD 1303 is a storage for accumulating image data, programs, font data, and forms, and the operation panel 1310 receives input operations from the operator and directs them to the operator. It is an operation unit for displaying.

Therefore, the ASIC 1301 has a ME
A RAM interface for connecting the M-C 1302 and a hard disk interface for connecting the HD 1303 are provided, and when inputting / outputting image data to / from these storage units, the input / output destination is RA.
Switch to M interface or hard disk interface.

The AGP 1308 is a bus interface for a graphics accelerator card, which has been proposed for accelerating graphics processing, and makes the graphics accelerator card faster by directly accessing the system memory with high throughput.

The input processing, the image processing and the output processing that can be provided by the multifunction machine 1200 having the above-described functional configuration shown in FIG. 1 and the hardware configuration shown in FIG. 2 are connected via a network. Image input / output application 1216 and transfer application 121 that can be used from other devices
A functional configuration example of No. 7 will be described. FIG. 3 is a diagram illustrating a functional configuration example of the image input / output application and the transfer application. In FIG. 3, the image input / output application 1216 mainly controls the process flow control module 450 that controls the process flow of the input process, the image process, and the output process, and the flow of the screen displayed on the operation panel 1302 via the OCS 1226. And a UIF (User InterFace) control module 430.

The processing flow control module 450 is a scanner 1324 as an image reading device for inputting an image.
An input control module 410 for controlling the input image, an output control module 420 for controlling a plotter 1321 as an image forming apparatus for outputting an image, and an image processing module for performing image processing on the input image data 601 to generate output image data 602. 440 and each module 41
The process flow of each input process, the image process, and the output process performed at 0, 440, and 420, or the series of process flows as a whole is controlled. For example, the fusion machine 1200
When the input processing, the image processing, and the output processing are continuously performed, the processing flow control module 450 controls each processing according to a predetermined processing flow. Further, as will be described later, in the case of only the requested processing, the processing flow control module 450 controls the corresponding module so that only the requested processing is performed according to the predetermined processing flow.

The UIF control module 430 has an input UIF 460 for providing an input screen, an output UIF 470 for providing an output screen, and an image processing UIF 480 for providing an image processing screen, and according to a display flow. Each UIF 46 is set so that a predetermined screen is displayed on the operation panel 1302 via the OCS 1226.
0, 470 and 480 are controlled.

Referring to FIG. 3, first, a mechanism in which the UIF control module 430 displays an input screen, an image processing screen, and an output screen on the operation panel 1302 of the compound machine 1200 will be described.

When the compound machine 1200 is activated, the processing flow control module 450 acquires available device configurations such as the scanner 1324 and plotter 1321 from the SCS 1222 as system information 452. The input control module 410 uses the system information 452 to scan the scanner 132.
4 confirms the functions that can be provided by 4, such as the document feeder function and the double-sided document reading function, and acquires them as the input option information 433. The input UIF 460 of the UIF control module 430 is based on the input option information 433 acquired by the input control module 410, and includes text, buttons, icons, and the like that configure an input screen that displays the functions for input processing that the scanner 1324 can provide. An input screen coordinate parameter 462 indicating the images and the position coordinates where they are arranged is generated. Input UI
Input screen coordinate parameter 4 generated by F460
62 indicates the OCS1 by the UIF control module 430.
226 is notified, and is displayed as an input screen on the operation panel 1302 by the OCS 1226 based on the input screen coordinate parameter 462. When the user sets a desired function from the input screen displayed on the operation panel 1302, the position coordinates where the image of the text, button, icon, etc. selected by the user is displayed are input to the UIF control module 430 via the OCS 1226. UIF 460 is notified.

The input UIF 460 is based on the input option information 433 and the input screen coordinate parameter 462.
The function corresponding to the position coordinates notified from the OCS 1226 is notified to the input control module 410 as the input setting parameter 434, and the image input is instructed. The input control module 410 executes the scanner application 1214 based on the input setting parameter 434 to execute the scanner 1
324 is controlled, the input image 600 is read, and the function set by the user is executed with respect to the input image 600. Input image data 601 is generated as a result of being executed by the scanner 1324 under the control of the input control module 410.

Further, the image processing module 440 displays the image processing functions that can be provided by the multi-function peripheral 1200 from the system information 452, such as the aggregate print function or the copy function, the frame erasing function, the reverse function, the stamp function and the like. Image processing UIF480 as processing option information 435
Notify to. Image processing U of UIF control module 430
Based on the image processing option information 435 notified from the image processing control module 440, the IF 480 is an image such as a text, a button, or an icon that constitutes an image processing screen that displays the image processing functions that the multifunction peripheral 1200 can provide. And an image processing screen coordinate parameter 482 indicating the position coordinates where they are arranged. Image processing UIF
The image processing screen coordinate parameter 482 generated by the 480 is output by the UIF control module 430 to the OCS.
1226, and the image processing screen coordinate parameter 4
Based on 82, the image is displayed on the operation panel 1302 by the OCS 1226 as an image processing screen. When the user sets a desired function from the image processing screen displayed on the operation panel 1302, the position coordinates where the image of the text, the button, the icon, etc. selected by the user is displayed are displayed on the UI via the OCS 1226.
The image processing UIF 480 of the F control module 430 is notified.

The image processing UIF 480 notifies the image processing control module 440 of the function corresponding to the position coordinates notified from the OCS 1226 as the image processing setting parameter 436 based on the image processing option information 435 and the image processing screen coordinate parameter 482. And instruct image processing. The image processing control module 440 executes image processing on the input image data 601 generated by the input control module 410, and as a result, generates output image data 602.

Similarly, when the compound machine 1200 is activated, the output control module 420 causes the system information 45
2 to check the functions that can be provided by the plotter 1321, for example, finisher functions such as punching function and stapling function, sorting function, stacking function, print number setting function, paper tray type, double-sided paper feeding function, and output them It is acquired as option information 431. The output UIF 470 of the UIF control module 430 is based on the output option information 431 acquired by the output control module 410, and includes a text, a button, an icon, and the like that configure an output screen that displays an output processing function that can be provided by the plotter 1321. An output screen coordinate parameter 472 indicating the images and the position coordinates where they are arranged is generated. Output UIF
Output screen coordinate parameter 47 generated by 460
2 by the UIF control module 430 OCS12
26, the operation panel 1 is operated by the OCS 1226 based on the output screen coordinate parameter 472.
It is displayed on 302 as an output screen. When the user sets a desired function from the output screen displayed on the operation panel 1302, the text selected by the user,
The position coordinates at which images such as buttons and icons are displayed are displayed on the UIF control module 4 via the OCS 1226.
30 output UIF 470 is notified.

The output UIF 470 is based on the output option information 431 and the output screen coordinate parameter 472.
The function corresponding to the position coordinates notified from the OCS 1226 is notified as the output control setting parameter 432 to the output control module 420, and the image output is instructed. The output control module 420 controls the plotter 1321 using the printer application 1211 based on the output setting parameter 432, and the image processing module 440.
The output image data 602 generated by is output from the plotter 1321 as an output image 603 formed as an image on paper or the like.

For the control by the UIF control module 430, for example, the image processing screen is displayed on the operation panel 13.
02, the screen for setting the frame width for frame deletion is displayed, or the output screen is displayed on the operation panel 1.
When displayed on 302, the screen flow control is changed so as to display a screen indicating a position where the staple is to be hit. Further, the input option information 433, the image processing option information 435, and the output option information 431 also include a program for controlling the operation panel 1302. Further, the input option information 433 and the output option information 431 as described above are the information of the scanner operation including the information of the paper document and also the information about the operation (control) of the ADF (Automatic Document Feeding Device). . The output option information 431 is information relating to the finisher of the printing paper, and is not limited to the printer processing and is the same when the copy processing is used.

When making a normal copy, input settings relating to image input, for example, settings such as single-sided original or double-sided original, and image processing related to image processing are performed on the input screen displayed on the operation panel 1302. Settings such as frame erasing and output settings related to image output, such as stapling and paper tray settings, are made, and copying is started by the copy start button.

Upon the start of copying, the input control module 4
10 receives the input setting parameter 434, and starts input of the input image 600 according to the input setting parameter 434. The input image 600 input is taken in as input image data 601 by the multi-function peripheral 1200, and the image processing module 440 is executed according to the image processing setting parameter 436.
The input image data 601 image-processed by is passed to the output control module 420 as output image data 602. The output image data 602 is output as an output image 603 to the plotter 1321 by the output control module 420 according to the output setting parameter 432.

In order to make the input processing, image processing, and output processing functions that can be provided by the multi-function peripheral 1200 available from another device connected via the network, the transfer application 1217 is provided from the other device. NCS122 in response to a request for each input, image processing and output option information of
Optional information 433, 43 by FTP3 of 8
5 and 431 are transferred.

When the transfer application 1217 receives a request for input option information from another device connected via the network, the transfer application 1217 simultaneously outputs the input option information 433 for displaying the functions that can be provided by the multi-function peripheral 1200 to the FTP3.
The file is transferred to the other device by. Similarly, when the transfer application 1217 receives a request for image processing option information or output option information from another device connected via the network, the transfer application 1217 sends the image processing option information 435 or the output option information 431 to the other device by FTP3. Forward.

By downloading and using each option information transferred in this way by another device, the other device can display a plurality of functions provided by the multi-function peripheral 1200. Further, the setting parameter indicating the function set by the user is transmitted to the multi-function peripheral 1200. The multi-function peripheral 1200 replaces the received setting parameter with the corresponding setting parameter among the input setting parameter 434, the image processing setting parameter 436, and the output setting parameter 432 of the multi-function peripheral 1200.
It is possible to perform processing according to the settings of the user who is using the other device in the compound machine 1200.

In the functional configuration example of the image input / output application 1216 shown in FIG. 3, the input control module 410, the image processing module 440, the output control module 420, and the UI.
The F control module 430 may be realized by, for example, a Java (registered trademark) program. In this case, a Java (registered trademark) VM (Vi that enables execution of a Java (registered trademark) program indicated by a dotted line
rtual memory) 450 may be provided. Input option information 433, image processing option information 435
The output option information 431 is Java (registered trademark).
It is provided with a data structure that can be used by the program. If a Java (registered trademark) program can be executed in another device connected to the multi-function peripheral 1200 via a network, the input option information 433 and the image processing option information 43 can be obtained without depending on the hardware of the other device.
5 and output option information 431 can be provided.

For example, when the device connected to the compound machine 1200 via the network is a device having a lower function than the compound machine 1200 or only one kind of function (hereinafter referred to as a single function image processing device). The user who uses this single-function image processing apparatus can input the input option information 433, the image processing option information 435, and the output option information 431 of the multifunction machine 1200 to the single-function image processing apparatus.
Is acquired from the multifunction machine 1200,
The high functionality provided by the 200 can be utilized. A processing pattern for using the advanced functions of the multifunction machine 1200 in the single-function image processing apparatus will be described with reference to FIG. FIG. 4 is a diagram showing a processing pattern when the function of the multi-function peripheral is used. The input process, the image process, and the output process are performed by the user, that is, assuming that the side performing the display process is the single-function image processing device, or the single-function image processing device side or the multifunction machine 120.
The processing pattern in the case of performing on the 0 side is shown.

First, the processing pattern in which the input processing is performed by the single-function image processing apparatus, the image processing is performed by the multi-function peripheral 1200, and the output processing is performed by the single-function image processing apparatus is referred to as processing pattern 1. For example, as a situation where this processing pattern 1 is performed, it is desired to use the frame erasing function of the compound machine 1200 as a function of image processing, but the compound machine 12 is located far from the user's position.
00 and there is a single function image processing apparatus nearby, or a case where the multifunction peripheral 1200 is being used by another user.

Next, the input processing is performed by the compound machine 1200,
The processing pattern in which the image processing is performed by the multifunction machine 1200 or the single-function image processing apparatus and the output processing is performed by the multifunction machine 1200 is referred to as a processing pattern 2. For example, as a situation in which the processing pattern 2 is performed, an ADF (Automatic Docu
ment feeding device) as a function of input processing, and the stapling function of the compound machine 1200 as a function of output processing. Furthermore, if the frame erasing function which is not provided in the single function image processing apparatus but can be provided by the compound machine 1200 is desired, the compound machine 1
There may be a case where image processing is performed at 200.

A processing pattern in which the input processing is performed by the single-function image processing apparatus, the image processing is performed by the multifunction machine 1200 or the single-function image processing apparatus, and the output processing is performed by the multifunction machine 1200 is referred to as a processing pattern 3. For example, this processing pattern 3
There is a case where the single function image processing apparatus is required to perform the input processing and to use the stapling function of the multifunction peripheral 1200 as the output processing. Further, there may be a case where the multifunction machine 1200 is caused to perform image processing when it is desired to use the frame erasing function which is not provided in the single function image processing apparatus but can be provided by the multifunction machine 1200.

Further, input processing is performed by the multi-functional machine 1200,
The processing pattern in which the image processing is performed by the multifunction machine 1200 or the single-function image processing apparatus and the output processing is performed by the single-function image processing apparatus is a processing pattern 4. For example, this processing pattern 4
There is a case where the ADF provided in the multi-function peripheral 1200, which is not included in the single-function image processing apparatus, is desired to be used as the input processing function. Further, there may be a case where the multifunction machine 1200 is caused to perform image processing when it is desired to use the frame erasing function which is not provided in the single function image processing apparatus but can be provided by the multifunction machine 1200.

In the same manner as above, display processing is performed by the multi-function peripheral 120.
Although it is naturally conceivable that the processing is performed at 0 and other combinations, the purpose of the present invention can be sufficiently shown by describing the above four processing patterns.

These processing patterns 1 to 4
An example of a screen that displays the functions of the multi-function peripheral 1200 on the operation panel of the single-function image processing apparatus as shown in FIG.
The processing flow will be described. In the following description, a copier is assumed as the single function image processing device. For convenience of explanation, an example of a screen displayed on the operation panel of the single-function image processing apparatus will be described. However, each option information 433, 435, and 431 to be displayed is the multifunction machine 1200.
The same display is possible on the operation panel 1302 of the multi-function peripheral machine 1200.

First, an example of an input screen based on the input option information 433 will be described with reference to FIG. FIG. 5 is a diagram showing an example of the input screen. In FIG. 5, the input screen G600 is
A button 61 for designating a device for input processing, a button 62 for designating a device for image processing, a button 63 for designating a device for output processing, and a user showing a list of devices existing on the network. A display area 610, and a display area 620 selectable by the user indicating functions that can be processed by the device selected by the user from the display area 610.

When the user selects the button 61 on the input screen G600, the display area 610 displays a list of inputtable devices existing on the network. In the display area 610, for example, "copy machine" indicating the single-function image processing apparatus itself, "multi-function machine" indicating the multi-function machine 1200 described above as a device on the network, and "device 0".
Device names such as "1", "device 02", "device 03", and "device 04" are displayed. For example, when the user selects “multifunction machine”, the display area 620 displays functions that the “multifunction machine” can provide as input processing.

For example, in the display area 620, the input image 60
"Character" for reading 0 in character mode, input image 6
"Photo" to read 00 in the photo mode, "Automatic density" to set the density setting to "Fusion", "Light" and "Dark" for the user to set the density, one side of the input image 600 Functions such as "single-sided" for inputting only one side and "double-sided" for inputting both sides of the input image 600 are displayed. For example, if the user has "photo"
And “single-sided” are selected, input setting parameters indicating the functions of “photograph”, “automatic density” and “single-sided” corresponding to the selected position coordinates are generated and transmitted to the multi-function peripheral 1200. The image input / output application 1216 of the fusion machine 1200 is
The received input setting parameter is input setting parameter 43
4 and the input control module 410 reads the input image 600 from the scanner 1324 using the function indicated by the input setting parameter 434 (that is, “photograph”, “automatic density”, and “single-sided”).

A processing flow between the multifunction machine 1200 and the single-function image processing apparatus, which is performed according to the user's operation on the input screen G600, will be described with reference to FIG. Figure 6
FIG. 6 is a flowchart illustrating a processing flow for realizing display of an input screen of the multi-function peripheral on a single function image device.

In FIG. 6, the input screen G6 displayed by the user on the operation panel of the single-function image processing apparatus.
When the button 61 for designating a device for input processing is selected with 00 (step S611), the single-function image processing device
The presence of an image-capable device among the devices connected via the network is confirmed (step S612). As a confirmation method, all the devices existing on the network may be confirmed by broadcasting, or confirmation may be made with respect to a preset specific device. In response to the presence confirmation from the single-function image processing device, the multi-function peripheral 1200 existing on the network responds to the single-function image processing device with device-specific information including an IP address for identifying the multi-function peripheral 1200, a device name, and the like ( Step S61
3). Upon receiving the device-specific information from the multi-function peripheral 1200 and each device on the network, the single-function image processing device displays a list of device names of each device in the display area 610 of the input screen G600.

When the user selects, for example, the compound machine 1200 (step S614) as the device for performing the input process from the displayed area 610 (step S614), the single-function image processing apparatus informs the compound machine 1200 of the input option information 43.
3 is requested (step S615). Fusion machine 1200
Transmits the input option information 433 to the single-function image processing apparatus by FTP3 in response to the request from the single-function image processing apparatus (step S616).

When the single function image processing apparatus receives the input option information 433 from the compound machine 1200, the single function image processing apparatus generates an input screen coordinate parameter using the input option information 433 and is displayed on the operation panel of the single function image processing apparatus. In the display area 620 of the input screen G600, the fusion machine 1
The functions that can be provided by the 200 are displayed (step S
617). For example, when the user selects “photograph”, “automatic density”, and “single-sided” from the display area 620 in which the function is displayed (step S618), the input UIF 112 causes “photograph”, “corresponding to the selected position coordinate” to be displayed. Input setting parameters indicating the functions of "automatic density" and "single-sided" are generated and transferred to the multifunction machine 1200 (step S6).
19).

The multifunction machine 1200 sets the received input setting parameter as the input setting parameter 434, and the input control module 410 sets the input setting parameter 43.
4 to read the input image 600 from the scanner 1324 and generate the input image data 601 (step S6).
20).

By setting the input setting parameter received by the multi-functional apparatus 1200 as the input setting parameter 434, the input control module 410 can perform the input processing as if the user set the operation panel 1302 of the multi-functional apparatus 1200. You can Upon completing the input processing, the image input / output application 1216 transmits the input result to the single-function image processing apparatus (step S6).
21). The single-function image processing apparatus displays the input result received from the compound machine 1200 on the operation panel (step S622).

With such a processing flow, the user can select a desired function from the function list that can be provided by the multi-function peripheral 1200 displayed on the operation panel of the single-function image processing apparatus, and can select the desired function. It is possible to cause the multifunction peripheral 1200 to perform the input processing based on the input processing. For example, even if the user does not have a “photograph” function in the single-function image processing apparatus, the user can cause the multifunction machine 1200 to perform an input process in which the “photograph” function is one of the input setting options. it can.

In the processing flow shown in FIG. 6, the case where the single function image processing apparatus and the multifunction machine 1200 are used has been described, but it is also realized between two multifunction machines 1200 or two single function image processing apparatuses. It is possible.

Next, an example of an image processing screen based on the image processing option information 435 will be described with reference to FIG. FIG. 7 is a diagram showing an example of the image processing screen. In FIG. 7, since the image processing screen G630 has the same screen configuration as the input screen G600, the same parts as those in FIG. 5 are denoted by the same reference numerals, and the description thereof will be omitted. When the user selects the button 62 on the image processing screen G630, the display area 610 displays a list of image-processable devices existing on the network, similar to the input screen G600. When the user selects "multifunction machine", the display area 620 displays a function in which "multifunction machine" can be set as image processing.

For example, in the display area 620, "frame deletion" for deleting shadows around the paper, "reverse" for reversing and copying the image color, "stamp" indicating that image processing has been completed, and dirt on the input image "Removal of background stains" for correction, "1x" for processing at the same size as the image, "Paper specified magnification" for processing at the magnification corresponding to the specified paper, and 100% for specifying the magnification of the image using the numeric keypad. "Display" for designating image processing including display, "Edit" for repeatedly processing images on one sheet or combining different images to process on one sheet, "1" for left and right pages Functions such as "division" for processing the sheets one by one are displayed. For example, when the user selects “frame deletion”, “actual size” and “division” as the image processing for one left and right page, “frame deletion”, “actual size” and The image processing setting parameter indicating the function of “division” is generated and transmitted to the multi-function peripheral 1200. The image input / output application 1216 of the compound machine 1200 sets the received image processing setting parameter as the image processing setting parameter 436, and the image processing control module 440 sets the image processing setting parameter 440.
Output image data 602 is generated by performing image processing on the input image data 601 using the function (that is, “frame deletion”, “actual size”, and “division”) designated by.

A processing flow between the multi-function peripheral 1200 and the single function image processing apparatus, which is performed according to the user's operation on the image processing screen G630, will be described with reference to FIG.
FIG. 8 is a flow chart for explaining the processing flow for realizing the display of the multi-function peripheral and the input screen in the single function image device.

In FIG. 8, when the user selects the button 62 for designating the device for image processing on the image processing screen G630 displayed on the operation panel of the single function image processing apparatus (step S651), the single function image processing apparatus is The presence of a device capable of image processing among the devices connected via the network is confirmed (step S65).
2). The confirmation method performed by the broadcast or the specific device is the same as the case of the processing flow for realizing the display of the input screen described in FIG. In response to the presence confirmation from the single-function image processing apparatus, the multi-function peripheral 1200 existing on the network is assigned an IP address for identifying the multi-function peripheral 1200,
It responds to the single-function image processing device with device-specific information including the device name and the like (step S653). Upon receiving the device-specific information from the multi-function peripheral 1200 and each device on the network, the single-function image processing device displays a list of device names of each device in the display area 610 of the input screen G600.

When the user selects, for example, the compound machine 1200 (step S654) as the device for performing image processing from the display area 610 displayed, the single-function image processing apparatus notifies the compound machine 1200 of the image processing option information. 435 is requested (step S655). Fusion machine 120
0 transmits the image processing option information 435 to the single function image processing apparatus by FTP3 in response to the request from the single function image processing apparatus (step S656).

Upon receiving the image processing option information 435 from the multi-function peripheral 1200, the single function image processing apparatus uses the image processing option information 435 to generate the image processing screen coordinate parameter and displays it on the operation panel of the single function image processing apparatus. The functions that can be provided by the multi-function peripheral 1200 are displayed in the display area 620 of the displayed image processing screen G630 (step S657). Display area 6 showing functions
From 20, for example, when the user selects “frame deletion”, “normal size” and “division” (step S658), the image processing UIF 113 causes the “frame deletion”, “normal size” and An image processing setting parameter indicating the function of “division” is generated and transferred to the multi-function peripheral 1200 (step S659).

Image input / output application 121 of the fusion machine 1200
6 acquires the input image data 601 (step S6)
60). When the input processing is not performed by the multifunction peripheral 1200, the image input / output application 1216 acquires the input image data 601 from the single function image processing device. The image input / output application 1216 sets the image processing setting parameter received from the single-function image processing apparatus as the image processing setting parameter 436, and the image processing control module 440 sets the input image data 60 according to the image processing setting parameter 436.
Image processing is performed on 1 to generate output image data 602 (step S661).

By setting the image processing setting parameter received by the image input / output application 1216 as the image processing setting parameter 436, the image processing control module 4
The image processing device 40 can perform image processing as if set by the user on the operation panel 1302 of the compound machine 1200. Upon completing the image processing, the multi-function peripheral 1200 transmits the image processing result to the single-function image processing apparatus (step S662). The single-function image processing apparatus displays the image processing result received from the compound machine 1200 on the operation panel (step S663).

In the processing flow shown in FIG. 8, the case where the single function image processing apparatus and the multifunction machine 1200 are used has been described, but it is also realized between two multifunction machines 1200 or two single function image processing apparatuses. It is possible. With such a processing flow, the user can select a desired function from the function list that can be provided by the multi-function peripheral 1200 displayed on the operation panel of the single-function image processing apparatus.
It is possible to cause the multifunction peripheral 1200 to perform image processing based on the selection.

Further, an example of an output screen based on the output option information 431 will be described with reference to FIG. FIG. 9 is a diagram showing an example of the output screen. In FIG. 9, the output screen G640 has the same screen configuration as the input screen G600, and therefore, the same parts as those in FIG. 5 are denoted by the same reference numerals and the description thereof will be omitted. When the user selects the button 63 on the output screen G640, the display area 610 displays a list of output-processable devices existing on the network, similar to the input screen G600. When the user selects "Machine",
In the display area 620, the functions that can be set as the output processing by the “multifunction machine” are displayed.

For example, in the display area 620, “sort” is output for each page in order of pages, “stack” is output for each page, “staple” indicating how to staple with four types of staples by icons, and two types of staples are displayed. A function such as "punch" that indicates how to punch a hole with an icon is displayed. For example,
When the user selects any one of the plurality of icons indicating the position of the staple displayed on the "staple", the output setting parameter indicating the "staple" function which specifies the binding corresponding to the selected position coordinate is generated. , To the multifunction machine 1200. The image input / output application 1216 of the multi-function peripheral 1200 sets the received output setting parameter as the output setting parameter 432, and the output control module 420 has the function corresponding to the position coordinates designated by the output setting parameter 432 (that is, “staple”). Output image data 602 using the "sort" and "staple" which are automatically set by selecting ".
An image is formed on a sheet by 21 and output as an output image 603.

A processing flow between the multi-function peripheral 1200 and the single-function image processing apparatus, which is performed according to the user's operation on the output screen G600, will be described with reference to FIG. FIG. 10 is a flowchart illustrating a processing flow for realizing display of an output screen with a compound machine in a single-function image device.

In FIG. 10, the output screen G displayed by the user on the operation panel of the single-function image processing apparatus.
When the button 63 for designating the device to perform the output process is selected at 640 (step S671), the single-function image processing apparatus confirms the presence of the device capable of image output among the devices connected via the network (step S671). S67
2). The confirmation method performed by the broadcast or the specific device is the same as the case of the processing flow for realizing the display of the input screen described in FIG. In response to the presence confirmation from the single-function image processing apparatus, the multi-function peripheral 1200 existing on the network is assigned an IP address for identifying the multi-function peripheral 1200,
It responds to the single-function image processing device with device-specific information including the device name and the like (step S673). Upon receiving the device-specific information from the multi-function peripheral 1200 and each device on the network, the single-function image processing device displays a list of device names of each device in the display area 610 of the output screen G640.

When the user selects, for example, the compound machine 1200 from the display area 610 in which the image is displayed (step S674), the single-function image processing apparatus instructs the compound machine 1200 to output the option information 43.
1 is requested (step S675). Fusion machine 1200
Transmits the output option information 431 to the single function image processing apparatus by FTP3 in response to the request from the single function image processing apparatus (step S676).

Upon receiving the output option information 431 from the multi-function peripheral 1200, the single-function image processing apparatus uses the output option information 431 to generate output screen coordinate parameters, which are displayed on the operation panel of the single-function image processing apparatus. In the display area 620 of the output screen G640, the fusion machine 1
The functions that can be provided by the 200 are displayed (step S
677). By this execution, the functions that can be provided by the compound machine 1200 are displayed in the display area 620 of the output screen G640 displayed on the operation panel of the single-function image processing apparatus. For example, when the user selects one of the icons indicating the position of “staple” from the display area 620 in which the function is displayed (step S678), the output UIF
The output setting parameter indicating the function of "staple" corresponding to the selected position coordinate is generated by 114, and is transferred to the multi-function peripheral 1200 (step S679).

Image input / output application 121 of the fusion machine 1200
6 acquires the output image data 602 (step S6)
80). When the output processing is not performed by the multi-function peripheral 1200, the image input / output application 1216 acquires the output image data 602 from the single-function image processing apparatus. The image input / output application 1216 sets the output setting parameter received from the single-function image processing apparatus as the output setting parameter 431, and outputs the output image data 602 to the output control module 420.
Is output as an output image 603 formed on a sheet according to the output setting parameter 431 (step S
681).

By setting the output setting parameter received by the image input / output application 1216 as the output setting parameter 431, the output control module 420 performs the output processing as if the user set the operation panel 1302 of the multifunction machine 1200. can do. When the output processing is completed, the image input / output application 1216 transmits the image processing result to the single-function image processing apparatus (step S682). The single-function image processing apparatus displays the output result received from the compound machine 1200 on the operation panel (step S683).

In the processing flow shown in FIG. 10, the case where the single function image processing apparatus and the multifunction machine 1200 are used has been described, but it is also realized between two multifunction machines 1200 or two single function image processing apparatuses. It is possible. With such a processing flow, the user can select a desired function from the function list that can be provided by the multi-function peripheral 1200 displayed on the operation panel of the single-function image processing apparatus, and output based on the selection. It is possible to cause the multi-function peripheral 1200 to perform the processing.

The processing patterns by the combination of the input processing, the image processing and the output processing shown in FIG. 4 using the user interface realized by the screens and the processing flows described in FIGS. This will be described in detail in 14. Single Function Image Processing Device 100
Is, for example, a single copy machine that provides only a copy function, and includes, for example, an input processing unit 102 that reads an input image 600 formed on a sheet, and input image data that is generated by reading the input image 600. An image processing unit 104 that performs image processing on the image processing apparatus, an output processing unit 106 that forms output image data that has been subjected to the image processing on a sheet and outputs the output image 603, and an operation panel 120 operated by a user. , And an operation control unit 116 that controls display on the operation panel 120.

Further, the operation control section 110 generates an input screen coordinate parameter (not shown) for displaying an input screen G600 as shown in FIG. 5 on the operation panel 120, and an input UIF 112. An image processing UIF 113 for generating image processing screen parameters (not shown) for displaying the image processing screen G630 as shown in FIG. 7, and an output screen G64 as shown in FIG.
It has at least an output processing UIF 114 that generates an output screen coordinate parameter (not shown) for displaying 0, and an OCS 116 that controls the operation panel 120 by each user interface 112 to 114.

Further, the operation control unit 110 has a Java (registered trademark) VM 118 when the user interface program for realizing each of the user interfaces 112 to 114 is a Java (registered trademark) program. On the other hand, in the single-function image processing apparatus 100, the OCS 1 is configured by configuring each processing unit of the operation control unit 110 to be realized by a Java (registered trademark) program.
Even when there is no 16, it is possible to maintain the affinity with the compound machine 1200.

11 to 14, the Java (registered trademark) VM 450 and the Java (registered trademark) VM are shown.
The portions indicated by dotted lines except 118 are provided as constituent elements, but are not used in the example of the processing pattern. In addition, a portion indicated by a double line indicates a portion replaced with the data file transmitted from the compound machine 1200 or the single-function image processing apparatus 100. Processing Pattern 1 FIG. 11 is a diagram showing an example of processing pattern 1 shown in FIG. In FIG. 11, display processing, input processing, and output processing are performed by the single-function image processing apparatus, and only image processing is performed by the multifunction machine 1200.

First, the user operates the operation panel 1
When the single-function image processing apparatus 100 itself is selected from 20 as the device that performs the input processing, the input UIF 112 originally included in the single-function image processing apparatus 100 generates the input generated based on the input option information 156 of the single-function image processing apparatus 100. Input screen functions that can be provided by the single-function image processing apparatus 100 are displayed on the operation panel 120 by a screen coordinate parameter (not shown). When the user selects a function, the input UIF 112 generates an input setting parameter (not shown) indicating the function set by the user. The input processing unit 102 reads the input image 600 according to the input setting parameter (not shown) indicating the function set by the user, which is generated by the input UIF 112, and generates the input image data 601.

Next, the user operates the operation panel 1
When the multi-function peripheral 1200 is selected from 20 as the device for performing image processing, the image processing option information (not shown) of the existing image processing UIF 113 is obtained from the multi-function peripheral 1200 according to the processing flow shown in FIG. 435. Image processing UIF113
OCS based on the image processing option information 435.
Multifunction machine 1 on the operation panel 120 via 116
The image processing functions that the 200 can provide are displayed. When the user selects a function, the image processing UIF 113 displays the image processing setting parameter 13 indicating the function set by the user.
6 is generated. The single-function image processing apparatus 100 transfers the image processing setting parameter 136 and the input image data 601 generated by the input processing unit 102 to the multifunction peripheral 1200 as a file. The input image data 601 corresponds to the multifunction machine 12
00 may be transferred in response to a request from the image input / output application 1216.

In the multifunction machine 1200, the image processing setting parameter 136 received from the single-function image processing apparatus 100.
Then, the image processing setting parameter 436 of the image input / output application 1216 is replaced. Then, the image processing module 440 performs image processing on the input image data 601 received from the single-function image processing apparatus 100 based on the image processing setting parameter 436, and generates output image data 602 as a result. Output image data 602
Is transferred to the single-function image processing apparatus 100.
The output image data 602 may be transferred in response to a request from the single-function image processing apparatus 100.

Further, when the user operates the operation panel 1
When the single-function image processing apparatus 100 itself is selected as the device that performs output processing from 20, the output UIF 114 originally included in the single-function image processing apparatus 100 generates the output generated based on the output option information 157 of the single-function image processing apparatus 100. The function of output processing that can be provided by the single-function image processing apparatus 100 is displayed on the operation panel 120 by the screen coordinate parameter (not shown). When the user selects a function, the output UIF 114 generates an output setting parameter (not shown) indicating the function set by the user. The output processing unit 106 forms the output image data 602 on a sheet or the like according to the output setting parameter (not shown) generated by the output UIF 114 and indicating the function set by the user, and outputs it as the output image 603.

As described above, the user can cause only the image processing to be performed by the compound machine 1200 connected via the network 15. Processing Pattern 2 FIG. 12 is a diagram showing an example of the processing pattern 2 shown in FIG. In FIG. 12, only the display process is performed by the single-function image processing device, and the input process, the image process, and the output process are performed by the multifunction machine 1.
Performed at 200.

In FIG. 12, the multifunction machine 12 is used as a device for the user to perform input processing, image processing and output processing from the operation panel 120 of the single-function image processing apparatus 100.
If 00 is selected, input option information (not shown) of the existing input UIF 112 is followed according to the processing flow of FIG.
Is the input option information 4 acquired from the compound machine 1200.
33. The input UIF 112 displays the input processing function that can be provided by the multi-function peripheral 1200 on the operation panel 120 via the OCS 116 based on the input option information 433. When the user selects a function, the input UIF 112 generates an input setting parameter 134 indicating the function set by the user. The single-function image processing apparatus 100 transfers the input setting parameter 136 to the multifunction peripheral 1200 as a file.

In the multifunction machine 1200, the input setting parameter 134 received from the single-function image processing apparatus 100
Input setting parameters 434 of the image input / output application 1216
Is replaced. The input image 600 is read by the input control module 410, and the input image data 601 is generated by the multifunction machine 1200.

Similarly, according to the processing flow of FIG. 8, the existing image processing UI in the single-function image processing apparatus 100 is used.
The image processing setting indicating the image processing function set by the user from the image processing screen of the multifunction peripheral 1200 displayed based on the image processing option information 435 in which the image processing option information (not shown) used by the F113 is replaced. The parameter 136 replaces the image processing setting parameter 436 of the compound machine 1200. In accordance with the replaced image processing setting parameter 436, the image processing module 440 causes the output image data 60
Generates 2.

Further, similarly, according to the processing flow of FIG. 10, the existing output UIF1 in the single-function image processing apparatus 100 is also used.
By the output process setting parameter 132 indicating the function of the output process set by the user from the output screen of the compound machine 1200 displayed based on the output option information 431 in which the output option information (not shown) used by 14 is replaced. The output processing setting parameter 432 of the compound machine 1200 is replaced. The output processing module 420 outputs the output image 603 according to the replaced output setting parameter 432.

As described above, the user can cause the multi-function peripheral 1200 connected via the network 15 to perform all of the input processing, the image processing and the output processing. Further, the image processing may be performed by the single function image processing 100. In that case, the single-function image processing apparatus 100 acquires the input image data 601 from the multi-function peripheral 1200, and performs the image processing on the input image data 601 to output the output image data 6
02 together with the output setting parameter 132
Configured to send to 200. Processing Pattern 3 FIG. 13 is a diagram showing an example of the processing pattern 3 shown in FIG. In FIG. 13, display processing and input processing are performed by a single-function image processing apparatus, and image processing and output processing are performed by the multifunction machine 1.
Performed at 200.

In FIG. 13, the user selects the single-function image processing 100 itself as a device for performing input processing from the operation panel 120 of the single-function image processing apparatus 100, and performs the image processing and output processing as a multi-function machine 1.
If you select 200, the single-function image processing device 100
The input image 600 is read by the input processing unit 102, and the input image data 600 is generated. Then, Figure 1
Similarly to the processing pattern 1 of No. 1, the single-function image processing apparatus 10
At 0, the existing image processing option information (not shown) is replaced with the image processing option information 435 of the multifunction machine 1200. Then, in the image input / output application 1216 of the multifunction machine 1200, the image processing module 440 generates the output image data 602 according to the image processing setting parameter 436 replaced by the image processing setting parameter 136 received from the single-function image processing apparatus 100. To do. Further, similar to the processing pattern 2 in FIG. 12, the existing output option information (not shown) in the single-function image processing apparatus 100 is replaced with the output option information 431 of the multi-function peripheral 1200. After that, in the image input / output application 1216 of the multifunction machine 1200, the output module 420 outputs the output image 603 according to the output setting parameter 432 replaced by the output setting parameter 132 received from the single-function image processing apparatus 100.

As described above, the user performs only the input processing in the single-function image processing apparatus 100, and the image processing and the output processing are connected via the network 15.
It can be done at zero. Further, the image processing may be performed by the single function image processing 100. In that case,
The single-function image processing apparatus 100 is configured to transmit output image data 602 obtained by performing image processing on the input image data 601 generated by the input processing unit 102, to the multi-function peripheral 1200 together with the output setting parameter 132. Processing Pattern 4 FIG. 14 is a diagram showing an example of processing pattern 4 shown in FIG. In FIG. 14, display processing and output processing are performed by a single-function image processing apparatus, and input processing and image processing are performed by the multifunction machine 1.
Performed at 200.

In FIG. 14, the single function image processing apparatus 1 is used as a device for a user to perform input processing and output processing from the operation panel 120 of the single function image processing apparatus 100.
00 itself is selected, and when the multi-function peripheral 1200 is selected as a device for performing image processing, the existing input IOF in the single-function image processing apparatus 100 is the same as the processing pattern 2 in FIG.
The input option information 112 (not shown) is the multi-function peripheral 12
00 input option information 433. Then, in the image input / output application 1216 of the multi-function peripheral 1200, the input control module 410 according to the input setting parameter 434 replaced by the input setting parameter 134 received from the single-function image processing apparatus 100,
Input image data 601 is generated. Furthermore, in the single-function image processing apparatus 100, the existing image processing option information (not shown) is the image processing option information 43 of the multifunction peripheral 1200.
Is replaced by 5. Then, in the image input / output application 1216 of the fusion machine 1200, the single-function image processing apparatus 10
According to the image processing setting parameter 436 replaced by the image processing setting parameter 136 received from 0, the image processing module 440 sets the output image data 60
Generates 2. Then, the single-function image processing device 100
Obtain the output image data 602 from the multi-function peripheral 1200,
Output processing is performed by the existing output processing unit 106 and output as an output image 603.

As described above, the user can cause the multifunction peripheral 1200 to perform the input processing and the image processing from the single-function image processing apparatus 100, and can cause the single-function image processing apparatus 100 to perform the output processing after the image processing. it can. Further, the image processing may be performed by the single function image processing 100. In that case, the single-function image processing apparatus 100 is the multifunction machine 1
Output image data 602 obtained by acquiring input image data 601 from 200 and performing image processing on the input image data 601.
Together with the output setting parameter 132
It is configured to send to 0.

In the processing patterns 1 to 4, the multi-function peripheral 1200 and the single-function image processing apparatus 100 are connected to the network 1
Although the example in which the image processing apparatuses are connected via 5 has been described, the present invention can be applied to a mode in which three or more image processing apparatuses are connected.

As described above, in the first embodiment, an option (ADF, double-sided AD) attached to the compound machine 1200 connected by the network 15 from an arbitrary image processing apparatus is used.
The input image 600 can be input using (F, etc.). For example, if the input image 600 (original) is a double-sided ADF1
An image can be continuously input from a plurality of double-sided originals using a multifunction machine 1200 equipped with 350 and output to a single-function image processing apparatus 100 (copier) having only a pressure plate.

Further, by using an option (finisher, punch, staple, etc.) attached to the multifunction machine 1200 from the arbitrary single-function image processing apparatus 100 on the network 15 to the multifunction machine 1200 connected by the network 15, The output image 603 can be output. For example, it is possible to output an image from a single-function copy machine or personal computer (PC) by using the output option of a full-function, high-function printer or copy machine. At this time, since the image processing option information 435 is acquired via the network 15, it is not necessary to newly prepare a user interface in the single-function image processing apparatus 100 operated by the user, and the multifunction peripheral 1200 can provide it from anywhere. You can give instructions using the same operation as the interface. Network 1 is a device with new functions added
5, even if the existing single-function image processing apparatus 100 on the operating side does not know the function, the user can
The interface for operating the functions of the compound machine 1200 can be used as it is.

Further, if the high-performance multifunction peripheral 1200 exists on the network 15, the input image data 601 is sent to the multifunction peripheral 1200, and the output image data 602 is sent to the single function image processing apparatus 100 on the output side. Accordingly, even in the single-function image processing apparatus 100 that does not have high-performance image processing, the same function can be realized. At this time,
Single-function image processing apparatus 1 on the operation side for image processing functions and settings
Even if the user does not know 00, the processing can be performed by the same operation from any device.

In this embodiment, the network 15
Only a plotter 1321 of the compound machine 1200 as an output option, a scanner 1324 of the compound machine 1200 as an input option, and a single-function image processing apparatus 100 (copier) as an input and output option are provided above, but a plurality of them are provided. Is also possible. All options, for example, devices connected to the network 15 or scanners, printers, copiers, etc. as functions, can share the respective functions. Further, the output destination is not limited to printing on paper, and electronic data may be used for storing and storing documents in a server or the like. Alternatively, the input side may be a document management server, a document management server, and electronic data instead of paper originals. In this way, by storing as a document, it is possible to reuse the data that already exists as image data, and the frequently used data can be stored in the network 15.
You can use it with various output methods that use options just by setting it above.

[0132]

As described above, according to the present invention, each user interface for performing the input process, the image process and the output process and the option information indicating the function executable in each process are networked. It can be provided to another image processing apparatus via. Therefore, when using the image processing apparatus on the network, the user interface can be unified and processed regardless of which image processing apparatus on the network is operated. Also,
Since the function set by the user can be received as a setting parameter via the network, the user can cause another image processing apparatus on the network to perform processing according to the setting parameter.

Further, according to the present invention, the existing display unit can select the input side image processing apparatus for inputting the image data and the output side image processing apparatus for outputting the image data among the plurality of image processing apparatuses. . Image data can be transferred from the input image processing device to the output image processing device and output. Therefore, the user does not need to implement the image processing function even with a personal computer having no image processing function, nor to prepare a special user interface for setting or inputting necessary information. Various requests for image input / output can be easily made via the network.

[0134]

[Brief description of drawings]

FIG. 1 is a block diagram showing a functional configuration of a compound machine that combines various image forming functions according to a first embodiment of the present invention.

FIG. 2 is a block diagram showing a hardware configuration of a compound machine 1200 shown in FIG.

FIG. 3 is a diagram illustrating a functional configuration example of an image input / output application and a transfer application.

FIG. 4 is a diagram showing a processing pattern when the function of the multi-function peripheral is used.

FIG. 5 is a diagram showing an example of an input screen.

FIG. 6 is a flowchart illustrating a processing flow for realizing display of an input screen with a multi-function peripheral in a single-function image device.

FIG. 7 is a diagram showing an example of an image processing screen.

FIG. 8 is a flowchart illustrating a processing flow for realizing display of an input screen with a compound machine in a single-function image device.

FIG. 9 is a diagram showing an example of an output screen.

FIG. 10 is a flowchart illustrating a processing flow for realizing the display of the multi-function peripheral and the output screen on the single-function image device.

11 is a diagram showing an example of a processing pattern 1 shown in FIG.

12 is a diagram showing an example of a processing pattern 2 shown in FIG.

13 is a diagram showing an example of a processing pattern 3 shown in FIG.

14 is a diagram showing an example of a processing pattern 4 shown in FIG.

[Explanation of symbols]

100 single-function image processing device 1200 fusion machine, 1210 software group 1216 image input / output application, 1217 transfer application 1218 document list application 1230 application, 1220 platform 1221 OS, 1222 SCS 1223 SRM, 1224 ECS 1225 MCS, 1226 OCS 1227 FCS, 1228 NCS 1229 IMH, 1240 Multifunction machine starting unit 1300 Controller, 1301 ASI
C 1302 MEM-C, 1303 HD 1304 CPU, 1305 NB 1306 MEM-P, 1307 SB 1308 AGP, 1310 Operation panel 1320 Fax control unit 1330 USB, 1340 IEEE
E1394 1350 Engine part, 1500 Network I / F part 1510 Printer, 1520 Scanner 1530 FAX unit

   ─────────────────────────────────────────────────── ─── Continued front page    F-term (reference) 2C061 AP01 AP03 AP04 AP07 HN04                       HN26 HP06                 5B021 AA01 BB00 PP05                 5C062 AA05 AA35 AB17 AB20 AB22                       AC38 AE15 AF14 BA00                 5E501 AA06 AA07 AA15 AC25 BA05                       DA12 DA13 EB05 FA03 FA23

Claims (13)

[Claims] 1. A screen generation means for generating screen information for displaying a plurality of function options based on option information indicating a plurality of function options that can be set for a predetermined process, and is connected via a network. In response to a request from the device used by the user, the user sets the transfer means for transferring the option information and the plurality of function options displayed by the device using the option information from the device. An image forming apparatus comprising: a processing control unit which, when receiving a setting parameter indicating a function option, controls the predetermined processing by using a hardware resource for performing the predetermined processing based on the setting parameter. 2. The predetermined process is a process relating to image formation, which manages an application having the image generation control means and the processing control means, the hardware resources, and responds to a use request from the application. 2. The image forming apparatus according to claim 1, further comprising a control service that controls utilization of the hardware resource, and an operating system that controls the application and the control service. 3. Device identification information including a device address for specifying the image forming device on the network and a device name in response to a request from the device for confirming whether or not the predetermined process is possible. 3. The image forming apparatus according to claim 1, further comprising a response unit that responds by. 4. The input screen generation means for generating the input screen information for displaying the plurality of input function options based on the input option information indicating the plurality of input function options related to the image input processing as the screen generation means. An image processing screen generation unit that generates image processing screen information that displays the plurality of image processing function options based on the image processing option information that indicates the plurality of image processing function options related to the image processing; 4. At least one of output screen generation means for generating output screen information for displaying the plurality of output function options based on output option information indicating the output function option of 4. 2. An image forming apparatus according to claim 1. 5. An input control means for controlling input processing of an image to generate input image data as the processing control means, and an image to generate image output data for performing image processing on the input image data to output. 5. At least one of processing control means and output control means for controlling output processing for forming an image on a medium and outputting the image based on the image output data. The image forming apparatus according to the item. 6. The image forming apparatus according to claim 5, wherein the input control unit controls the scanner as the hardware resource for performing the input processing. 7. The image forming apparatus according to claim 5, wherein the output control unit controls a plotter as the hardware resource for performing the output processing. 8. The input screen transfer means for transferring the input option information related to the input processing designated by the request to the apparatus as the transfer means, and the image processing screen for transferring the image processing option information about the image processing to the apparatus. 7. The image forming apparatus according to claim 1, further comprising at least one of transfer means and output screen transfer means for transferring output option information regarding output processing to the apparatus. 9. Based on first option information indicating a plurality of first function options that can be set for a predetermined process,
Screen generation means for generating first screen information for displaying the plurality of first function options based on option information indicating, and processing by the device transmitted from a device selected by a user connected through a network. Based on the second option information indicating the possible multiple second feature options
Set by the user from replacement means for replacing the first screen information with the second screen information displaying the plurality of second function options, and the plurality of second function options displayed based on the second screen information. An image forming apparatus, comprising: a processing request unit that requests the apparatus to perform the predetermined processing by transmitting a setting parameter indicating the one or more second function options to the apparatus. 10. The screen generation means, based on input option information indicating a plurality of input function options related to image input processing, input for generating, as the screen information, input screen information for displaying the plurality of input function options. An image processing screen generating means for generating image processing screen information for displaying the plurality of image processing function options as the screen information based on image processing option information indicating a plurality of image processing function options related to image processing. And at least one of output screen generation means for generating output screen information for displaying the plurality of output function options as the screen information based on output option information indicating a plurality of output function options related to image output processing. The image forming apparatus according to claim 9, wherein 11. An input setting parameter indicating one or more input function options set by the user from among a plurality of input function options that can be set by the device for the input processing, as the processing request means. Input processing requesting means for requesting the input processing to the apparatus by transmitting to the apparatus, and one of a plurality of image processing function options settable for the image processing by the apparatus set by the user. Image processing requesting means for requesting the image processing of the device by transmitting the image processing setting parameter indicating the image processing function option described above to the device, and a plurality of image processing setting means that can set the output process by the device. Output setting parameter indicating one or more output function options set by the user from the output function options. 11. The image forming apparatus according to claim 9, further comprising at least one of output processing requesting means for requesting the output processing to the apparatus by transmitting the data to the apparatus. 12. A screen generation procedure for generating screen information for displaying a plurality of function options based on option information indicating a plurality of function options that can be set for a predetermined process, and is connected via a network. In response to a request from the device used by the user, a transfer procedure for transferring the option information and a plurality of function options displayed by the device using the option information set by the user are set by the user. An image forming method comprising: a process control procedure that receives a setting parameter indicating a function option and controls the predetermined process by using a hardware resource for performing the predetermined process based on the setting parameter. 13. A first screen for displaying a plurality of first function options based on option information indicating a plurality of first function options that can be set for a predetermined process. Based on a screen generation procedure for generating information, and second option information indicating a plurality of second function options that can be processed by the device, which is transmitted from the device selected by the user connected through the network,
Set by the user from a replacement procedure for replacing the first screen information with the second screen information displaying the plurality of second function options and the plurality of second function options displayed based on the second screen information. An image forming method, comprising: a processing request procedure for requesting the apparatus to perform the predetermined processing by transmitting a setting parameter indicating the one or more second function options to the apparatus.