JP3647180B2 - Interface device and method thereof - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention has a feeder for feeding and discharging a plurality of documents. Image forming apparatus The present invention relates to an interface device between a computer and a host computer and a method thereof.
[0002]
[Prior art]
In recent years, emphasis has been placed on the function of a multifunction device capable of performing printing and scanning in response to commands from a host computer in a digital color copying machine. Accordingly, there is an increasing need to use this feeder when executing control such as printing and scanning of a digital color copying machine from a host computer.
[0003]
[Problems to be solved by the invention]
In addition to the types of originals such as single-sided and double-sided originals, there are a number of operation modes for feeding and discharging paper set on the feeder depending on how the user places the original in the feeder. Must be specified from the host computer. Further, in order to move the feeder of the digital color copying machine in accordance with the operation mode designation from the host computer, it is necessary to convert the command from the host computer into a command that can be recognized by the feeder of the digital color copying machine.
[0004]
According to the present invention, as specified by the host computer, depending on the type of document on the feeder and how to place the document, Image forming apparatus Feeder certainly Make it work, Image forming apparatus It is an object of the present invention to provide an interface device and method for a computer and a host computer.
[0005]
[Means for solving problems]
In order to achieve the above object, an interface device according to claim 1 comprises: a host computer; , It has a paper supply / discharge means for supplying and discharging documents. Image forming apparatus Communication means for communicating with the host computer, and the communication means Through Receiving a control command for controlling the paper supply / discharge means from the host computer Receiving means to , Said Control command received Is a control command that requests at least one of the operation mode of scanning the front side of the document placed on the platen and the mode of scanning the back side And analyzing means for analyzing the analysis action mode The , Based on a predefined conversion table, Image forming apparatus Converting means for converting the command sequence into a recognizable command sequence, and the command sequence converted by the converting means Image forming apparatus And other communication means for transmitting to the network.
[0006]
The interface device according to claim 2 is the interface device according to claim 1, wherein the control command is ,Previous Command issued as a trigger to actually operate the recording and discharging means including It is characterized by that.
[0007]
The interface device according to claim 3 is the claim 1 or 2. The interface device according to 2, wherein control The commands are: presence / absence of paper feeding operation, presence / absence of paper ejection operation, presence / absence of scanning operation of Specified including It is a command.
[0008]
The interface device according to claim 4 is the claim 1 to 3 Any one of In the described interface apparatus, the paper supply / discharge unit can send a plurality of originals without performing a scanning operation.
[0009]
The interface device according to claim 5 is the claim 1 to 3 Any one of In the described interface apparatus, the paper supply / discharge unit can rescan the scanned document without discharging the scanned document.
[0010]
In order to achieve the above object, an interface method according to claim 6 comprises: , It has a paper supply / discharge means for supplying and discharging documents. Image forming apparatus In the interface method for connecting to the host computer, a communication step of communicating with the host computer, and the communication step Through A control command for controlling the paper supply / discharge unit is received from the host computer. Receiving means to , Said Control command received Is a control command that requests at least one of the operation mode of scanning the front side of the document placed on the platen and the mode of scanning the back side The analysis process for analyzing and the analysis process action mode The , Based on a predefined conversion table, Image forming apparatus Converting to a command sequence that can be recognized, and the command sequence converted in the conversion step Image forming apparatus And the other communication process to transmit to.
[0011]
The interface method according to claim 7, wherein the control command is the interface method according to claim 6. ,Previous Command issued as a trigger to actually operate the recording and discharging means including It is characterized by that.
[0012]
The interface method according to claim 8 is characterized in that: 6 or 7. The interface method according to claim 7, wherein control The commands are: presence / absence of paper feeding operation, presence / absence of paper ejection operation, presence / absence of scanning operation of Specified including It is a command.
[0013]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, the present invention will be described in detail with reference to the preferred embodiments shown in the drawings.
[0014]
FIG. 1 is a connection schematic diagram of a system configuration of an interface apparatus according to an embodiment of the present invention. Reference numeral 101 denotes an interface (I / F) device, and reference numeral 102 denotes a host computer. The host computer 102 is connected to the I / F device 101 via an interface cable 106 made of a general-purpose interface such as SCSI, and transfers computer graphics (CG) image data to the frame memories 201 and 202 of the I / F device 101. To do. The host computer 102 can control the entire system by sending a control command to the I / F device 101.
[0015]
The digital color copiers 103 and 104 having a scanner / printer function are connected to scanner / printer interfaces 223 and 224 (to be described later) of the I / F device 101 via interface cables 107 and 108. Images stored in the frame memories 201 and 202 in the I / F device 101 can be printed out using the digital color copying machines 103 and 104. In addition, images read by the scanners of the digital color copying machines 103 and 104 can be stored in the frame memories 201 and 202 in the I / F device 101. These digital copying machines 103 and 104 can also store images read from the scanner in the frame memories 201 and 202 in the I / F device 101 in the same manner as the host computer 102. Similar to the host computer 102, these digital copying machines 103 and 104 can also control the entire system from their operation units.
[0016]
Reference numerals 109 and 110 denote film scanners which are connected to the scanner / printer interfaces 223 and 224 of the I / F apparatus 101 via the interface cables 111 and 112, and read from the scanners 109 and 110 in the same manner as the digital color copying machines 103 and 104. The stored images can be stored in the frame memories 201 and 202 in the I / F device 101. In place of these film scanners 109 and 110, a device for capturing video images such as a high definition television (HDTV) or other various image capturing devices may be connected. Images can be stored in the frame memories 201 and 202 in the same manner.
[0017]
The I / F device 101 can output the images stored in the frame memories 201 and 202 as a print output. Details of the I / F device 101 will be described later.
[0018]
FIG. 2 is a schematic configuration diagram of the digital color copying machines 103 and 104 having the digital color copying machine connected to the interface apparatus of FIG.
[0019]
The digital color copiers 103 and 104 are a digital color image reading unit (hereinafter referred to as a scanner) 400, a circulation type reflection original feeding device (hereinafter referred to as a feeder) 450 for setting an original on the scanner 400, and printing out a digital color image. A digital color image printing unit (hereinafter referred to as a printer) 500.
[0020]
The scanner 400 performs the following control mainly by the scanner controller 401.
[0021]
The exposure system controller 403 separates the original on the original table for each color of RGB by the contact CCD line sensor and converts it into a dot sequential analog image signal. This analog image signal is converted into an 8-bit digital image signal for each color by the A / D converter, and each RGB color as luminance data is output as a line sequential signal. The digital image signal is converted by the image processing unit 402 from RGB luminance levels to four colors of CMYBk having density levels corresponding to the toner amounts. Therefore, each color correction calculation is performed simultaneously by the image processing unit 402, and image processing such as composition, scaling, and movement is performed.
[0022]
In addition, the operation surface (not shown) of the scanner unit 400 has both a function of displaying a message to the user and a function of a touch sensor for operating and instructing each component of the color copying machines 103 and 104. An operation panel and a touch sensor are provided. The scanner unit 400 includes an operation panel controller 406 for controlling the operation panel / touch sensor.
[0023]
A feeder 450 is incorporated in the upper part of the document table of the scanner unit 400, and the feeder 450 is controlled by a feeder controller 405 in the scanner 400.
[0024]
The stacking tray 451 on which a bundle of documents is set is provided with a guide (not shown) that regulates the document in the width direction so that the document does not skew when the document is fed. This guide is perpendicular to the document feed direction. Move to slide. In conjunction with this guide, a slide volume (not shown) is operated to detect the size of the document in the width direction.
[0025]
First, single-sided originals are separated one by one from the lowermost part of the original bundle on the stacking tray 451 by the half-moon roller 453 and the separation roller 454, and the separated originals are brought into close contact with the path 1 while passing through the path 1. The paper length in the paper feeding direction is detected by the paper pattern width sensor 462, and further passes through the path 2 by the transport roller 455 and the entire surface belt 456 and is transported to the exposure position on the platen glass and stopped. After scanning, the original on the platen glass is returned again to the top of the original bundle by the large conveying roller 457 and the paper discharge roller 458. In the case of a small-size document, it is returned to the top of the document bundle again by the full-surface belt 456 and the paper discharge roller 461.
[0026]
Further, when the document feeding is started, a recycling lever 459 is placed on the upper part of the document bundle, the documents are sequentially fed, and it is detected that the trailing edge of the final document has fallen on the stacking tray 451 by its own weight when the recycling lever 459 is removed. Thus, one round of the document is detected.
[0027]
Next, in the case of a double-sided document, after scanning one side of the document as described above, the document is once passed through path 3 and the switching flapper 460 that can be rotated is switched to guide the leading edge of the document to path 4. The sheet is conveyed by the conveying roller 455 through the path 2 to the exposure position on the platen glass by the entire belt 456, and the other side of the document is scanned. That is, the original is reversed along the paths 3, 4, and 2 by the rotation of the large conveying roller 457.
[0028]
Further, the paper width sensor 462 counts the number of originals by conveying the originals until it is detected by the recycle lever 459 through the route 1, 2, 3, 5 and 6 of the original bundle one by one. Is also possible.
[0029]
The printer unit 500 is an electrophotographic laser beam printer. The printer unit 500 converts C, M, Y, and Bk digital image signals sent from the scanner unit 400 into lighting signals for the semiconductor laser unit. Controlled by the laser drive unit 510, the laser lighting signal is output as a pulse width corresponding to the level of the digital image signal. The laser lighting level is 256 levels (corresponding to 8 bits). In accordance with the digital image signal to be output, the color image is limited for each color of CMYBk, and the developing unit 516 sequentially exposes and develops the photosensitive drum 515 in a digital dot format, and the transfer unit 514 performs the photosensitive drum. A plurality of toners on the sheet 515 are transferred to a sheet, and then the toner transferred to the sheet is finally fixed by a fixing unit 522 through a transfer drum 519, a separation unit 520, and a conveyance unit 521.
[0030]
The feeder unit 450 and the printer unit 500 are controlled by the scanner unit 400, and as a result, they can also function as the digital color copiers 103 and 104.
[0031]
Next, the internal configuration of the I / F device 101 will be described. In FIG. 1, reference numeral 203 denotes a first CPU that controls I / Os other than the scanner and printer connected to the outside of the I / F device 101. Details thereof will be described later. A CPU bus 204 of the CPU 203 is connected to a SCSI controller 205 that interfaces with the host computer 102, a program memory 206, an I / O bus controller 207 that controls the I / O bus 208, and the like. A bus controller 211 is also connected so that it can be coupled to the CPU bus 210 of the second CPU 209. The CPU 209 will be described later.
[0032]
An I / O controller 212 is connected to the I / O bus 208, and includes a hard disk drive (HDD) 213, a floppy disk drive (FDD) 214, a keyboard (KBD) controller 215, a CRT controller 216, and a liquid crystal display (LCD). It controls general-purpose I / O such as the controller 217.
[0033]
Reference numeral 218 denotes a liquid crystal display device (LCD) that can always display the state of the I / F device 101. An operation unit 219 is connected to the keyboard controller 215 so that the initial setting of the I / F device 101 can be changed and the service mode can be set independently. If necessary, a monitor and a keyboard may be connected to the outside via the CRT controller 216 and the keyboard controller 215.
[0034]
Further, AUX slots 220 and 221 are prepared in the I / O bus 208. For example, various images stored in a CD-ROM can be developed in the frame memories 201 and 202 to obtain a print output. Multimedia support is possible.
[0035]
The CPU 209 controls I / O of the scanners and printers of the digital color copiers 103 and 104 connected to the outside, and further performs image rotation, image color space compression, and the like on the images stored in the frame memories 201 and 202. Processing can be performed. The memory 222 is a program memory, and is configured to load a control program from the hard disk drive 213 via the bus controller 211 when the power is turned on. The memory 222 is also used for communication with the CPU 203. Two types of scanner / printer interfaces (hereinafter simply referred to as interfaces) 223 and 224 are connected to the CPU bus 210 to control the scanner and printer while making various settings. Reference numeral 225 denotes an image-dedicated bus. When image scanning or printing is performed, image data flows through this bus.
[0036]
It is possible to connect to the interfaces 223 and 224 of the I / F device 101 even with different types of scanner printers such as an electrostatic photographic method and an inkjet method. According to this I / F device 101, devices of different methods can share the same frame memories 201 and 202, so there is no need to set a frame memory in advance for each device of a different method. Can use memory efficiently.
[0037]
In addition, these interfaces 223 and 224 are cards including a new interface board according to a copying machine method such as an electrophotographic method (hereinafter referred to as CLC method) or an ink jet method (BJ method) to be connected, or a speed. It can be replaced, and can be adapted to future system changes.
[0038]
Therefore, it is possible to flexibly cope with each connected device, and the expandability of the system is high. In this embodiment, in addition to the digital color copying machines 103 and 104, two types of film scanners 109 and 110 can be connected to the interfaces 223 and 224. The devices that can be connected to the interfaces 223 and 224 are not limited to the digital color copying machines 103 and 104 and the scanner printers 109 and 110 described above, and may be other devices such as an ink jet printer and a scanner.
[0039]
FIG. 3 is a configuration diagram of the interfaces 223 and 224 and the frame memories 201 and 202 in the interface apparatus of FIG. The frame memories 201 and 202 have the same configuration, and each includes red (R), green (G), and blue (B) plane memories 311 and 312 and memory controllers 301 and 302 that control the plane memories 311 and 312. . The memory controllers 301 and 302 perform control such as reading, writing and refreshing of image data in the plane memories 311 and 312 respectively.
[0040]
The above-described two frame memories 201 and 202 are independent of each other, that is, when one is printing, the other is transferring an image from the host computer 102 or developing a PDL image via the CPU bus 210, or as described above. Image processing using the CPU 209 can be performed.
[0041]
In addition, the two frame memories 201 and 202 can be connected and regarded as one memory. For example, when both have a memory capacity of A4 size, an A3 size image can be handled by connecting the two. it can.
[0042]
In the interfaces 223 and 224 in FIG. 3, the same circuits are denoted by the same reference numerals. The masking circuit 305 performs color processing for reproducing an image solidly such as masking and UCR calculation processing according to the color reproducibility of the connected output device. In this figure, for the sake of convenience, the case where the masking circuit 305 is arranged in the I / F device 101 is shown, but this masking circuit 305 may be arranged in the digital color copying machine 103, and in the following description. In the following description, it is assumed that the masking circuit 305 is disposed in the digital color copying machine 103.
[0043]
When reading and writing image data from the same frame memory, the FIFO 306 adjusts the writing timing of the image data to the frame memory. The selector 307 switches the image data path according to whether or not the write timing needs to be adjusted. The controller 303 controls each circuit described above.
[0044]
Hereinafter, a specific operation of the interface apparatus will be described on the assumption that the interface apparatus according to the present embodiment is connected to the interface 223 via the cable 107 and the CLC digital color copying machine 103. That is, an operation when an image stored in the plane memory 311 in the I / F device 101 is output using the digital color copying machine 103 based on a print command issued from the host computer 102 will be described.
[0045]
The CPU 203 receives a print command from the host computer 102 via the SCSI interface 205. Here, the CPU 203 and the SCSI interface 205 constitute communication means. The CPU 209 analyzes the command and writes the received command content in the memory 222 under the control of the bus controller 211. When the CPU 209 recognizes the writing of the command, it reads the contents of the memory 222 and executes the print command. The CPU 209 issues an instruction for issuing a print command to the digital color copying machine 103 to the controller 303 in the interface 223, and the controller 303 as another communication means sends the print command to the digital color copying machine 103 through communication via the cable 107. Issue.
[0046]
The cables 107, 108, 111, and 112 have the same structure, and image data 24 bits, a synchronization signal, a clock, and communication are accommodated in one cable bidirectionally.
[0047]
Upon receiving the printer command, the digital color copying machine 103 activates the printer 500 and simultaneously returns an image synchronization signal. The controller 303 that has received the image synchronization signal places an image request signal on the control bus in the video bus 225 in accordance with the image synchronization signal, and issues an image output request to the memory control 301 of the frame memory 201. The memory control 301 outputs RGB data 24 bits to the video bus 225 according to the image request signal. The output image data is input to the color conversion circuit 304 in the interface 223, and the image data in the predetermined RGB color space in the plane memory 311 is converted into the image data in the color space of the digital color copying machine 103, and masking is performed. The image data is transferred to the color copying machine 103 via the cable 107 via the circuit 305.
[0048]
The color space in this embodiment is a color expression method such as an RGB color space of image data from the host computer 102, an RGB color space unique to the digital color copying machines 103 and 104, or a CMYBk color space.
[0049]
The cable 107 synchronizes with the phenomenon of the image in the color copying machine 103, uses the full 24 bits of image data, and transfers the RGB image data four times for each color in frame sequential order. As a result, the RGB image data is read from the frame memory 201 a total of four times, and the same processing is performed.
[0050]
In the present embodiment, the image data is not limited to the image data transferred in the field sequential manner, but may be transferred in a dot sequential manner or the like, and the image data is transferred by a method supported by the output device.
[0051]
FIG. 4A is an explanatory diagram of the image data stored in the frame memories 201 and 202. FIG. 4B forms an image from the image data received by the digital color copying machine 103 from the interface 223. It is explanatory drawing of a method. In FIG. 4A, reference numeral 601 denotes image data stored in the frame memories 201 and 202. For example, a magenta electrostatic latent image in the AA line section of the image data 601 in FIG. The state of forming on the drum 602 is shown. Reference numeral 603 denotes a laser that emits a laser beam, which turns on and off the laser beam based on transferred image data, and forms an electrostatic latent image on the photosensitive drum 602 via the polygon mirror 604. The photosensitive drum 602 rotates in the rotation direction indicated by an arrow 606.
[0052]
A beam detection sensor 605 is provided at one end of the photosensitive drum 602. When the beam detection sensor 605 receives a laser beam from the polygon mirror 604, the image end is detected, and this is detected by a horizontal synchronization signal (hereinafter referred to as HSYNC). The image transfer is synchronized as a signal). FIG. 5 shows a timing chart of the HSYNC signal.
[0053]
Image formation is performed by repeating the above operation four times for each color.
[0054]
The above description is for the case where the LOG conversion circuit and the masking circuit are provided on the digital color copying machine 103 side. However, as shown in FIG. It is as follows. In this case, MCYBk image data is transferred using 8 bits out of 24 bits in the image data line inside the cable 107.
[0055]
Next, an operation of storing image data of a document obtained by using the scanner 400 of the digital color copying machine 103 in the frame memory 201 in reverse to the above operation will be described.
[0056]
The CPU 203 receives and recognizes a scan command from the host computer 102 via the SCSI interface 205. The CPU 209 issues a scan command by communication to the digital color copying machine 103 through the controller 303 in the interface 223. The digital color copying machine 103 manipulates the document based on the scan command, and uses the obtained image data in the RGB color space based on the input characteristics of the digital color copying machine 103 using the full 24-bit image data in the cable 107, Transfer as RGB image data.
[0057]
In the I / F device 101, the transferred RGB image data is input to the color conversion circuit 304 in the interface 223, the image data is converted into a color space according to the file type registered with the connected device, and the video bus 225. Output to. At the same time, the controller 303 outputs a capture request signal to the memory control 301 via the control bus, and the memory control 301 stores the image on the video bus 225 in the plane memory 311 based on the capture request signal.
[0058]
The above is the description of the frame memory 201. The same applies to the memory frame 202. When the controller 303 places a request signal on the control bus with respect to the memory control 302, the frame memory 202 starts its operation. At this time, the interfaces 223 and 224 are configured not to operate simultaneously in order to avoid a bus conflict of the controllers 303 and 304.
[0059]
The image input / output operation for the digital color copying machine 103 has been described above, but the digital color copying machine 104, the film scanners 109 and 110, and the like perform the same operation.
[0060]
FIG. 6 shows a signal configuration between an I / F device and a device such as a digital color copying machine or a film scanner. As described above, the image signal is transmitted through the 24-bit signal line. The image control signal is a control signal for transferring image data, and includes a pixel synchronization signal, a line synchronization signal, and a page synchronization signal. The communication control signal is a signal for performing operation instruction and state management by command / status serial communication. The sequence control signal is a signal for sending information indicating the power state of each device.
[0061]
FIG. 7 shows a module configuration of a control program downloaded to the program memory 222 immediately after power-on and operating on the CPU 209 side in this embodiment. A real-time OS module 701 is a real-time OS and manages a plurality of tasks. Each task is activated in an event driven manner. The boot module 702 is a task executed when the control program is started, and performs initial setting of various ICs and frame memories, identification of an interface board, and the like. The master device communication module 703 and the slave device communication module 704 are responsible for command communication with the digital color copying machines 103 and 104 or the film scanners 109 and 110, and the module 703 performs color copying while the I / F device 101 becomes the master side. This is a communication control task in which the machines 103 and 104 are slaves, and commands are issued from the I / F device 101, and the status is returned from the color copiers 103 and 104. The module 704 is a type opposite to that of the module 703, and is a communication control task in which a command is issued from the color copiers 103 and 104 and the status is returned by the I / F device 101.
[0062]
The host communication module 705 manages command communication with the CPU 203 and image transfer control. With this task, the command received from the host computer via the SCSI controller 205 is analyzed on the CPU 209 side, and an instruction to start processing is sent to the communication control task and the image processing task.
[0063]
The CLC color copier control unit module 706, the BJ color copier control unit module 707, and the film scanner control unit module 708 respectively input / output image data to / from the CLC color copier, BJ color copier, and film scanner. This is an image input / output control task that governs control. An image processing unit module 709 manages image processing such as image compression, expansion, rotation, mirror image, color space compression, and color space. The memory manager module 710 manages image files registered in the frame memories 201 and 202.
[0064]
FIG. 8 is a configuration diagram of the software system of the I / F device 101. The operation of the software system of the I / F device 101 will be described with reference to FIG. First, the real-time OS of the module 701 is started after the power is turned on, and a boot task 901 and a DOS manager task 902 described below are generated.
[0065]
The boot task 901 controls the module 702 and sets the card code in the configuration table of FIG. 9A at the time of each initial setting. The configuration table manages the boards set in the slots, that is, the interfaces 223 and 224 and whether or not the digital color copiers 103 and 104 and the film scanners 109 and 110 are connected to the slots.
[0066]
Although not shown, the interfaces 223 and 224 have a structure in which an interface board in which a board ID indicating a communication type for each board type is set in hardware is inserted into the slot, and each board inserted into the slot has a structure. The board ID can be read by the CPU 209, and the type of the interface board can be automatically identified corresponding to each slot. Based on this recognition, the engine card code shown in FIG. 9B is written in the corresponding slot location in the configuration table of FIG. 9A.
[0067]
Further, the power standby of the color copiers 103 and 104 and the film scanners 109 and 110 sent as sequence control signals on the interfaces 223 and 224 is viewed at a signal detection port on the interfaces 223 and 224 (not shown). Thus, if each device is activated, I / F control tasks 905, 906, and 907 are generated according to the engine card code in the configuration table of FIG. Tasks 906 and 907 perform communication control of the module 703 in which the I / F device 101 is the master side, and task 905 performs communication control of the module 704 in which the I / F device 101 is the slave side. Then, exchange of commands / status with the film scanners 109 and 110 is performed. Device code, cassette information, and the like are set in the device information table of FIGS. 9 and 10 based on the information obtained by this communication.
[0068]
Therefore, first, the interface board inserted is identified, and the communication type is set by managing the card code corresponding to the slot. Next, based on the set communication type, communication is performed with the connected device, and the device code shown in FIG. 9C and FIG. 9D is associated with each slot in FIG. It is set in the configuration table shown in FIG.
[0069]
Through the above processing, the I / F device 101 can automatically identify each connected device in association with the slot. In addition, since the connected device recognition process is performed every day when the power is turned on, it is possible to always grasp the system state of the latest I / F device.
[0070]
The task 902 controls the module 705 and has analysis means for analyzing the command received from the host computer 102. Tasks 906 and 907 have conversion means for converting the command analyzed in task 902 into a command sequence that can be recognized by the digital color copiers 103 and 104 based on a predefined conversion table. When a print / scan command is received, image input / output control tasks 908, 909, and 910 are activated via tasks 905, 906, and 907. At this time, the slot in which the I / F card is installed is selected by the parameter accompanying the print / scan command, and different image input / output control is performed for each device according to the device code in the configuration table of FIG. Accordingly, it is possible to switch between which device to scan or to print according to the use of the user. Furthermore, an image input / output task of a different control method such as the CLC method or the FS method can be operated according to the connected device.
[0071]
Next, the processing is executed via the task 902 in FIG. 8 for analyzing the command received from the host computer, and the tasks 906 and 907 for converting the command analyzed in the task 902 based on the predefined conversion table. A control process of the feeder 450 of the digital color copying machine 103 by the computer 102 will be described.
[0072]
(1) Basic control sequence
First, a command issued from the host computer 102 to the I / F device 101 will be described with reference to FIGS.
[0073]
In the flowchart of FIG. 16, when controlling the feeder 450 of the digital color copying machine 103 from the host computer 102, first, the remote command shown in FIG. 11 is issued to the I / F device 101, and the digital color copying machine 103 is controlled. The remote control is enabled (step S1601). Next, the document feed mode, the feed / discharge stop flag, and the number of document advance pages shown in FIG. 13 are designated by the RF control command of FIG. 12 (step S1602). Here, when the paper supply / discharge stop flag is set to 0, paper supply / discharge is performed. When it is set to 1, paper supply / discharge is not performed. Here, the document is fed one by one, the document feeding mode is set arbitrarily for scanning, the feeding / discharging stop flag is set to 0, and the number of forward pages is set to 0.
[0074]
Further, by issuing the scan file command of FIG. 14, the paper is actually fed from the feeder 450 according to the mode set by the RF control command of FIG. 12 (step S1603). By repeatedly issuing the RF control command shown in FIG. 12 and the scan file command shown in FIG. 14, various sheet feeding / discharging operations can be performed (steps S1604 to S1606). If only one document is fed and scanned one by one, only the scan file command shown in FIG. 14 is issued repeatedly. At this time, the next original is fed in the single-sided copy mode, and the original is reversed in the double-sided copy mode. Only the RF control command shown in FIG.
[0075]
Next, the document feeder mode in FIG. 13 is set to 0 by the RF control command to cancel the automatic feeder (RF) control (step S1607). Finally, when the RF control is canceled, the remote command in FIG. 11 is issued. Then, the digital color copying machine 103 is set in a state where local copying is possible (step S1608).
[0076]
The command issued from the host computer 102 to the I / F device 101 is analyzed by a task 902 in FIG. 8, and the command is digitally referenced with reference to a conversion table defined in advance in tasks 906 and 907 in FIG. A command sequence issued to the digital color copier 103 after being converted into a form that can be recognized by the color copier 103 will be described below.
[0077]
When the remote request for the remote command shown in FIG.
[0078]
Next, when the RF control command in FIG. 12 is received, the I / F device 101 holds the mode, refers to the conversion table defined when the scan file command is received in FIG. According to the mode requested by the RF control command of FIG. 12, a write start command including parameters such as DHmode, NS, FI, and FO is issued at least once to operate the digital color copier 103. Here, DHmode indicates how to supply and discharge the document table. The issue command DHmode will be described later in association with the actual operation. NS indicates the presence / absence of scanning, FI indicates the presence / absence of paper feed, and FO indicates the presence / absence of paper discharge. FIG. 17 shows the difference in operation of the digital color copying machine 103 depending on the settings of the parameters DHmode, NS, FI, and FO of the write start command. In FIG. 17, for example, the positive feed positive discharge is a single sheet positive feed positive discharge high speed operation mode.
[0079]
Finally, when the local request for the remote command shown in FIG. 11 is received from the host computer 102, the I / F device 101 issues a Remote status control command to the digital color copying machine 103, and the digital color copying machine 103 can be copied locally. Return to.
[0080]
The difference between the RF control commands in FIG. 12 regarding the control from the I / F device 101 to the digital color copying machine 103 in accordance with the document feed mode will be described below with reference to FIGS.
[0081]
a. Front (continuous, single side) paper feed (Figs. 18 and 19)
The remote request for the remote command shown in FIG. 11 is received from the host computer 102, and the remote status control command is issued from the I / F device 101 to the digital color copying machine 103, so that the digital color copying machine 103 can be remotely controlled. Thereafter, when the scan file command of FIG. 14 is received, a predefined conversion table is referred to based on the RF control command of FIG. 12, and the parameter is set to DHmode = 0 (positive feed / exhaust mode) or DHmode = 5 (single correct) The front / rear scan is executed by issuing a write start command with NS = 0 (with scan), FI = 1 (with paper feed), and FO = 0 (no paper discharge).
[0082]
After that, when the scan file command shown in FIG. 14 is continuously received, the scan is continuously performed based on the RF control command shown in FIG. 12, but the pre-defined conversion table is referred to at this time as well. Then, set the parameters and issue the write start command again to scan the surface.
[0083]
On the other hand, when the RF control command in FIG. 12 for canceling the RF control command (document discharge) is received instead of the scan file command and the scan is ended, the parameter is set to DHmode = 0 with reference to a predefined conversion table. (Normal feed correct discharge mode), DHmode = 5 (single sheet positive feed correct discharge mode), NS = 1 (no scan), FI = 0 (no paper feed), FO = 1 (paper discharge) A writing start command is issued and the document is discharged.
[0084]
Finally, when the local request for the remote command shown in FIG. 11 is received from the host computer 102, the I / F device 101 issues a remote status control command to the digital color copying machine 103, and the digital color copying machine 103 is ready for local printing. Return to.
[0085]
b. Back side feeding (FIGS. 20 and 21)
The remote request for the remote command shown in FIG. 11 is received from the host computer 102, and the remote status control command is issued from the I / F device 101 to the digital color copying machine 103, so that the digital color copying machine 103 can be remotely controlled. Then, when the scan file command of FIG. 14 is received, the predefined conversion table is referred to based on the RF control command of FIG. 12, and the parameters are DHmode = 3 (counter feed / reject mode), NS = 0 (with scan), When FI = 1 (with paper feed) and FO = 0 (no paper discharge) are set, a write start command is issued to perform back side scanning.
[0086]
If the scan file command shown in FIG. 14 is subsequently received, the scan is continued based on the RF control command shown in FIG. 12, but the parameter is also referred to by referring to the predefined conversion table. Is set, and the write command is issued again to scan the back side. On the other hand, when the RF control command in FIG. 12 for canceling the RF control command (document discharge) is received instead of the scan file command and the scan is terminated, the parameter is set to DHmode = 3 with reference to a predefined conversion table. (Reverse feeding / discharging mode), NS = 1 (no scanning), FI = 0 (no feeding), and FO = 1 (with discharging) are issued, and a writing command is issued to discharge the original.
[0087]
Finally, when the local request for the remote command shown in FIG. 11 is received from the host computer 102, the I / F device 101 issues a remote status control command to the digital color copying machine 103, and the digital color copying machine 103 is ready for local printing. Return to.
[0088]
c. Double-sided (front to back) paper feed (Figs. 22 and 23)
The remote request for the remote command shown in FIG. 11 is received from the host computer 102, and the remote status control command is issued from the I / F device 101 to the digital color copying machine 103, so that the digital color copying machine 103 can be remotely controlled. After that, when the scan file command of FIG. 14 is received, the predefined conversion table is referred to based on the RF control command of FIG. 12, and the parameters are DHmode = 5 (single sheet positive feed / exhaust mode), NS = 0 (with scan) ), FI = 1 (with paper feed) and FO = 0 (no paper discharge) are set, a writing start command is issued, and the front surface is scanned.
[0089]
When the next scan file command shown in FIG. 14 is received, the predefined conversion table is referred to, and parameters are first set to DHmode = 4 (reverse mode), NS = 0 (with scan), FI = 0 (no paper feed), FO Is set to 0 (no paper discharge), a writing start command is issued, the document is turned over, the back side is scanned, and parameters are subsequently set to DHmode = 4 (reverse mode), NS = 1 (no scan), After setting FI = 0 (no paper feed) and FO = 0 (no paper discharge), the writing start command is issued again to turn over the original. Here, the document is turned over once more so that the orientation of the front and back of the document is aligned when the document is discharged.
[0090]
Thereafter, when the scan file command of FIG. 14 is received, the scan is continuously performed based on the RF control command of FIG. 12, but the surface scan is similarly performed by referring to the predefined conversion table. Set the hour parameter and issue a write start command to scan the surface. On the other hand, when the RF control command in FIG. 12 for canceling RF control (document discharge) is received instead of the scan file command and scanning is terminated, the parameter is set to DHmode = 5 (refer to the predefined conversion table). Single sheet feed / discharge mode), NS = 1 (no scan), FI = 0 (no paper feed), FO = 1 (with paper discharge) are set and a writing command is issued to discharge the original. .
[0091]
If scanning is continued at this time, the original is turned over and the back side is scanned based on the RF control command shown in FIG. 12 when the next command is received, and the original is turned over or the original is discharged. However, this is realized by referring to a predefined conversion table, changing each parameter, and issuing a scan file command in the same manner.
[0092]
Finally, when the local request for the remote command shown in FIG. 11 is received from the host computer 102, the I / F device 101 issues a remote status control command to the digital color copying machine 103, and the digital color copying machine 103 is ready for local printing. Return to.
[0093]
d. Double-sided (back → front) paper feed (Figs. 24 and 25)
The remote request for the remote command shown in FIG. 11 is received from the host computer 102, and the remote status control command is issued from the I / F device 101 to the digital color copying machine 103, so that the digital color copying machine 103 can be remotely controlled. Thereafter, when the scan file command of FIG. 14 is received, the predefined conversion table is referred to based on the RF control command of FIG. 12, and the parameters are DHmode = 1 (reverse feed / exclude mode), NS = 0 (with scan), When FI = 1 (with paper feed) and FO = 0 (no paper discharge) are set, a write start command is issued to perform back side scanning.
[0094]
When the scan file command shown in FIG. 14 is received, a predefined conversion table is referred to, and parameters are first set to DHmode = 4 (reverse mode), NS = 0 (with scan), FI = 0 (no paper feed), FO Is set to 0 (no paper discharge), a writing start command is issued, the document is turned over, the front side is scanned, and parameters are subsequently set to DHmode = 4 (reverse mode), NS = 1 (no scan), After setting FI = 0 (no paper feed) and FO = 0 (no paper discharge), the writing start command is issued again to turn over the original. Here, the document is turned over once more so that the orientation of the front and back of the document is aligned when the document is discharged.
[0095]
Thereafter, when the scan file command of FIG. 14 is received, the scan is continuously performed based on the RF control command of FIG. 12. Set the hour parameter and issue a write start command to scan the back side. On the other hand, when the RF control command shown in FIG. 12 for canceling RF control (document discharge) is received instead of the scan file command and scanning is terminated, the parameter is set to DHmode = 1 (refer to a predefined conversion table). The document is ejected by issuing a write command with the reverse feed correct mode set, NS = 1 (no scan), FI = 0 (no paper feed), and FO = 1 (paper ejection).
[0096]
If scanning is continued at this time, the original is turned over and the surface is scanned based on the RF control command shown in FIG. 12 when the next command is received, and the original is turned over or the original is discharged. .
[0097]
Finally, when the local request for the remote command shown in FIG. 11 is received from the host computer 102, the I / F device 101 issues a remote status control command to the digital color copying machine 103, and the digital color copying machine 103 is ready for local printing. Return to.
[0098]
(2) Rescan
Hereinafter, a control sequence in a case where the original on the feeder 450 is once scanned and then the same original is rescanned will be described with reference to FIG. FIG. 26 is a flowchart of command procedures issued from the host computer 102 to the I / F device 101.
[0099]
When controlling the feeder 450 of the digital color copying machine 103 from the host computer 102, first, the remote command shown in FIG. 11 is issued to the I / F device 101 so that the digital color copying machine 103 can be controlled remotely. (Step S2601). Next, the document feed stop mode shown in FIG. 13, the paper feed / discharge flag, and the number of document advance pages are designated by the RF control command of FIG. 12 (step S2602). Here, the paper feed / discharge stop flag is set to 0. In this manner, the paper is fed / discharged, and the number of original forward pages is set to zero.
[0100]
Further, by issuing the scan file command of FIG. 14, the paper is actually fed from the feeder 450 in accordance with the mode set by the RF control command of FIG. 12, and the first scan is executed (step S2603). To perform the second scan continuously, the document feed mode and the feed / discharge stop flag shown in FIG. 13 are first executed by the RF control command of FIG. 12 while the digital color copier 103 is in a state where remote control is possible. In this case, the number of document advance pages is specified. Here, the document feed mode is set to the same mode as when the first document is scanned, the paper feed / discharge stop flag is set to 1, and the number of document feed pages is set to 0 (step S2604). Next, by issuing the scan file command of FIG. 14, according to the mode set by the RF control command of FIG. 12, the second scan is executed without feeding / discharging from the feeder 450 (step S2605).
[0101]
To perform the third scan after feeding, after issuing the RF control command of FIG. 12 (step S2606), the scan file command of FIG. 14 is issued (step S2607). Note that after step S2605, the scan file command of FIG. 14 only needs to be issued to perform the third scan (step S2607), and only the RF control command of FIG. Good (step S2606).
[0102]
Finally, at the time of canceling the feeder control, the remote command shown in FIG. 11 is issued, and the digital color copying machine 103 is set in a state where local copying is possible (step S2610).
[0103]
Hereinafter, the command issued from the host computer 102 to the I / F device 101 is analyzed by the task 902 in FIG. 8, and the command is referred to the conversion table defined in advance in the tasks 906 and 907 in FIG. A command sequence issued to the digital color copying machine 103 after being converted into a form that can be recognized by the digital color copying machine 103 will be described.
[0104]
When the remote request of the remote command shown in FIG. 11 is received from the host computer 102, a remote status control command is issued from the I / F device 101 to the digital color copying machine 103, and the digital color copying machine 103 is brought into a state where remote control is possible. . Next, when the RF control command in FIG. 12 is received, the I / F device 101 holds the mode, refers to the conversion table defined when the scan file command is received in FIG. According to the mode requested by the RF control command of FIG. 12, a write start command including parameters set to DHmode other than inversion and count mode, NS = 1, FI = 1, FO = x (x is an arbitrary value) Issuing, feeding and discharging, and the first scan is executed.
[0105]
When the I / F device 101 receives the RF control command in FIG. 12 for performing the second scan in succession, the I / F device 101 holds the mode, refers to the conversion table defined in advance when the scan file command is received in FIG. 12 includes parameters set to DHmode, NS = 1, FI = 1, and FO = 0 in the same mode as the first scan according to the mode requested by the RF control command in FIG. A write start command is issued and the second scan is executed.
[0106]
Thereafter, when the scan file command of FIG. 14 is received from the host computer 102, a write start command is issued, the same original is scanned again, and when the RF control command of FIG. For this reason, or referring to a conversion table defined in advance for paper discharge, a write start command is issued.
[0107]
Finally, when the local request for the remote command shown in FIG. 11 is received from the host computer 102, the I / F device 101 issues a remote status control command to the digital color copying machine 103, and the digital color copying machine 103 is ready for local printing. Return to.
[0108]
(3) Scan after multiple page advance
Hereinafter, with reference to FIG. 27, a case will be described in which a document on the feeder 450 is scanned after a plurality of pages are advanced. FIG. 27 is a flowchart of a command procedure issued from the host computer 102 to the I / F device 101.
[0109]
First, the remote command shown in FIG. 11 is issued, and the digital color copying machine 103 is brought into a state where remote control is possible (step S2701). Next, the document feed mode, the sheet feed / discharge flag, and the number of document advance pages shown in FIG. 13 are designated by the RF control command of FIG. 12 (step S2702). Here, the paper feed / discharge stop flag is set to 0, and the number of document advance pages is set to n (n is an arbitrary number) to perform paper feed / discharge (step S2703). Further, in accordance with the mode set by the RF control command by issuing the scan file command of FIG. 14, the number of pages n specified by the feeder 450 is advanced (step S2704), and then normal feeding is performed by the feeder 450 to perform scanning. Is realized (steps S2705, S2706).
[0110]
When the RF sequence is completed (YES in step S2707), the document is discharged by the RF control command in FIG. 12 (step S2708). When the feeder control is canceled, the remote command in FIG. The copy is ready (step S2709).
[0111]
Hereinafter, the command issued from the host computer 102 to the I / F device 101 is analyzed by the task 902 in FIG. 8, and the command is referred to the conversion table defined in advance in the tasks 906 and 907 in FIG. A command sequence issued to the digital color copying machine 103 after being converted into a form that can be recognized by the digital color copying machine 103 will be described.
[0112]
When the remote request of the remote command shown in FIG. 11 is received from the host computer 102, a remote status control command is issued from the I / F device 101 to the digital color copying machine 103, and the digital color copying machine 103 is brought into a state where remote control is possible. . Next, when the RF control command in FIG. 12 is received, the I / F device 101 holds the mode, refers to the conversion table defined when the scan file command is received in FIG. According to the mode requested by the RF control command, a write start command including parameters set to DHmode other than the count mode, NS = 1, FI = 1, FO = x (x is an arbitrary value) is a number of times less than or equal to n. Issue only once, and advance the original by n pages. The number m issued here will be described later. Subsequently, a write start command including parameters set to DHmode, NS = 1, FI = 1, FO = x (x is an arbitrary value) other than the count mode is issued, paper supply / discharge is performed, and scanning is performed. . Subsequently, according to a command received from the host computer 102, a predefined conversion table is referred to and a write start command is issued to the digital color copying machine 103.
[0113]
Finally, when the local request for the remote command shown in FIG. 11 is received from the host computer 102, the I / F device 101 issues a remote status control command to the digital color copying machine 103, and the digital color copying machine 103 is ready for local printing. Return to.
[0114]
a. Number m of write start commands issued when multiple pages are advanced
This is because the number of pages of one document differs depending on the document feed mode of the RF control command of FIG. 12, because one page is one page in the single-side mode, and two pages are one page in the duplex mode. In single-sided mode, it is only necessary to issue the write start command as many times as the number of sheets that you want to advance. However, for double-sided (front-to-back) feeding, a command to flip the fed paper over and then turn it over once more In order to issue, an extra write command is issued once every two pages. That is, in the double-side mode, it is necessary to issue m number of write commands, which is larger than the number n of advanced pages. However, instead of sending the DHmode as shown in FIG. 27 in order, by sending a write start command to the digital color copier 103 in another DHmode, two pages can be sent with one write start command. For even pages of two or more pages, two pages are sent by one write start command. For example, when 4 pages are advanced, 4 pages are sent with 2 write start commands, and when 5 pages are advanced, 4 pages are sent with 2 write commands, and the remaining 1 page is sent as 1 write start command. Send in.
[0115]
(5) When performing composite printing with the original on the platen
Hereinafter, a case where an image sent from the I / F device 101 and a document on the feeder 450 are combined (hereinafter referred to as document table combining) will be described with reference to FIG. FIG. 28 is a flowchart of command procedures issued from the host computer 102 to the I / F device 101.
[0116]
First, document table composition when a document is on a document table will be described. When the image in the I / F device 101 and the original on the platen are combined, first, the file ID of the image to be combined with the print file command shown in FIG. 15 used when printing the image in the normal I / F device 101. Is specified, the number of output sheets is set to 0, and the image is virtually printed. This operation is repeated as many times as desired to synthesize the images in the I / F device 101 to perform virtual printing.
[0117]
Next, by issuing the command with the file ID of the print file command in FIG. 15 set to 0xFF, the image that has been virtually printed so far and the image on the platen can be combined. When the document is on the document table, the remote command shown in FIG. 11 is issued to enable the digital color copying machine 103 to be remotely controlled (step S2801), and then the RF control command shown in FIG. The original paper feed mode, the paper feed / discharge stop flag, and the number of original forward pages are designated.
[0118]
Next, the file ID of the image to be printed is designated by the print file command shown in FIG. 15, the output number is set to 0, and the image is virtually printed (step S2803). This operation is repeated as many times as desired to synthesize an image in the I / F device 101 to perform virtual printing (step S2804).
[0119]
Further, by issuing a command in which the file ID of the print file command in FIG. 15 is set to 0xFF, according to the mode set by the RF control command in FIG. 12, the paper is fed from the feeder 450, the scan is executed, and so far The image is combined with the image in the virtual printed I / F device 101 (step S2805).
[0120]
Subsequently, the RF control command shown in FIG. 12 and the scan file command shown in FIG. 14 are issued to realize one-sheet feeding scan, rescan of the same document, and scan after advance.
[0121]
Finally, when the feeder control is canceled, the remote command shown in FIG. 11 is issued to make the digital color copying machine 103 ready for local printing (step S2810).
[0122]
Hereinafter, the command issued from the host computer 102 to the I / F device 101 is analyzed by the task 902 in FIG. 8, and the command is referred to the conversion table defined in advance in the tasks 906 and 907 in FIG. A command sequence issued to the digital color copying machine 103 after being converted into a form that can be recognized by the digital color copying machine 103 will be described.
[0123]
When the remote request of the remote command shown in FIG. 11 is received from the host computer 102, a remote status control command is issued from the I / F device 101 to the digital color copying machine 103, and the digital color copying machine 103 is brought into a state where remote control is possible. . Next, when the RF control command in FIG. 12 is received, the I / F device 101 holds the mode.
[0124]
Subsequently, when the print file command of FIG. 15 in which the number of output sheets is set to 0 is received, printing is virtually performed in the I / F device 101 by the number of times of reception of the print file command in FIG. Thereafter, when the print file command of FIG. 15 with the file ID set to 0xFF is received, the pre-defined conversion table is referred to, and the parameter is determined according to the mode requested by the RF control command of FIG. DHmode, NS, FI, and FO (NS = 1, others are arbitrary values) are issued to feed paper (in the case of re-scanning, no paper feed / discharge is performed), but scanning is not performed. Next, a print request with composition is issued to the digital color copying machine 103 by a reading start command, and the document table composition is executed. Subsequently, according to a command received from the host computer 102, a predefined conversion table is referred to and a write start command is issued to the digital color copying machine 103.
[0125]
Finally, when the local request for the remote command shown in FIG. 11 is received from the host computer 102, the I / F device 101 issues a remote status control command to the digital color copying machine 103, and the digital color copying machine 103 is ready for local printing. Return to.
[0126]
According to the I / F device 101 according to the present embodiment, in order to control the feeder 450 that feeds and discharges a plurality of documents, a control command from the host computer 102 is analyzed in task 902 and tasks 906 and 907 are performed. By converting the analyzed control command into a command sequence that can be recognized by the digital color copying machine based on a predefined conversion table, it is inherently complicated depending on the paper supply / discharge mode, the presence / absence of paper supply / discharge, and the presence / absence of scanning. The feeder 450 that requires a simple command sequence can be easily controlled from the host computer 102.
[0127]
【The invention's effect】
As described above in detail, according to the interface device according to claim 1 and the interface method according to claim 6, in order to control the sheet feeding / discharging means for feeding / discharging a plurality of documents, the host computer Control commands Is a control command that requests at least one of the operation mode of scanning the front side of the document placed on the platen and the mode of scanning the back side And analyzed action mode Based on a predefined conversion table, Image forming apparatus By converting the command sequence into a command sequence that can be recognized by the host computer, it is possible to easily control the paper supply / discharge unit that originally requires a complicated command sequence depending on the paper supply / discharge mode, the presence / absence of paper supply / discharge, and the presence / absence of scanning. Can In particular, it is possible to control whether the front side or the back side of the document placed on the platen is scanned by an instruction from the host computer, Accordingly, the feeder of the image forming apparatus can be reliably operated according to the instruction of the host computer in accordance with the type of document on the feeder and how to place the document.
[Brief description of the drawings]
FIG. 1 is a schematic diagram of a system configuration of an interface apparatus according to an embodiment of the present invention.
2 is a configuration diagram of a digital color copying machine connected to the interface apparatus of FIG. 1;
3 is a configuration diagram of a scanner / printer interface and a frame memory in the interface apparatus of FIG. 1. FIG.
4A is an explanatory diagram of image data stored in a frame memory, and FIG. 4B is an explanatory diagram of a method for forming an image from image data received by a digital color copying machine from an interface device. It is.
FIG. 5 is a diagram illustrating image transfer timing.
FIG. 6 is a configuration diagram of signals between an I / F device, a digital color copying machine, and a film scanner.
FIG. 7 is an explanatory diagram of a module configuration of an I / F device control program.
FIG. 8 is a system configuration diagram of software of the I / F device.
FIG. 9 is an explanatory diagram of a device information table.
FIG. 10 is an explanatory diagram of a device information table.
FIG. 11 is an explanatory diagram of a control command transmitted from the host computer to the I / F device.
FIG. 12 is an explanatory diagram of a control command transmitted from the host computer to the I / F device.
FIG. 13 is an explanatory diagram of a control command transmitted from the host computer to the I / F device.
FIG. 14 is an explanatory diagram of a control command transmitted from the host computer to the I / F device.
FIG. 15 is an explanatory diagram of a control command transmitted from the host computer to the I / F device.
FIG. 16 is a flowchart showing an example of a command procedure issued from the host computer to the I / F device.
FIG. 17 is an explanatory diagram of a difference in operation of the digital color copying machine depending on settings of parameters DHmode, NS, FI, and FO of a write start command.
FIG. 18 is an explanatory diagram of an operation of a document on a feeder during front side (continuous, one side) paper feeding.
FIG. 19 is an explanatory diagram of communication control between the I / F device and the digital color copying machine during front side (continuous, one side) paper feeding.
FIG. 20 is an explanatory diagram of an operation of a document on a feeder during back side paper feeding.
FIG. 21 is an explanatory diagram of communication control between the I / F device and the digital color copying machine at the time of back side paper feeding.
FIG. 22 is an explanatory diagram of an operation of a document on a feeder during double-sided (front-to-back) feeding.
FIG. 23 is an explanatory diagram of communication control between the I / F device and the digital color copier when double-sided (front to back) paper feeding.
FIG. 24 is an explanatory diagram of an operation of a document on a feeder during double-sided (back to front) paper feeding.
FIG. 25 is an explanatory diagram of communication control between the I / F device and the digital color copying machine when double-sided (back to front) paper feeding is performed.
FIG. 26 is a flowchart showing an example of a command procedure issued from the host computer to the I / F device.
FIG. 27 is a flowchart showing an example of a command procedure issued from the host computer to the I / F device.
FIG. 28 is a flowchart showing an example of a command procedure issued from the host computer to the I / F device.
[Explanation of symbols]
101 Interface device
102 Host computer
103, 104 Digital color copier
201, 202 frame memory
203 first memory
209 Second memory
223,224 Scanner / Printer Interface
301,302 Memory control
303 controller
304 color conversion circuit
305 Masking circuit
400 Digital color image reader (scanner)
450 Circulation-type reflective document feeder (feeder)
500 Digital color image print section (printer)

Claims (8)

In an interface device for connecting a host computer and an image forming apparatus having a paper supply / discharge unit for supplying and discharging a document,
Communication means for communicating with the host computer;
Receiving means for receiving a control command for controlling the paper supply / discharge means from the host computer via the communication means;
The received control command is an analysis means for analyzing whether the control command requesting at least one operation mode of the modes to scan mode and back to scan the surface of a document placed on a document table,
Conversion means for converting the operation mode analyzed by the analysis means into a command sequence that can be recognized by the image forming apparatus , based on a predefined conversion table;
Other communication means for transmitting the command sequence converted by the conversion means to the image forming apparatus
An interface device comprising: The control command interface apparatus according to claim 1, comprising a command to be issued as a trigger for actually operating the front Symbol feeding paper discharge means. Wherein the control command, the paper whether the paper feed operation in the sheet discharge means, the presence or absence of the paper discharge operation, the interface device according to claim 1 or 2, wherein the command is a command that includes a designation of whether the scanning operation. The paper sheet discharge means, interface apparatus according to any one of claims 1 to 3, characterized in that it is possible to send a plurality of originals without performing scanning operation. The paper sheet discharge means, interface apparatus according to any one of claims 1 to 3, characterized in that it is possible to re-scan the document without discharging the scanned document. In an interface method for connecting a host computer and an image forming apparatus having a paper supply / discharge unit for supplying and discharging a document,
A communication step of communicating with the host computer;
Receiving means for receiving a control command for controlling the paper supply / discharge means from the host computer via the communication step;
The received control command is an analysis step of analyzing whether the control command requesting at least one operation mode of the modes to scan mode and back to scan the surface of a document placed on a document table,
A conversion step of converting the operation mode analyzed in the analysis step into a command sequence that can be recognized by the image forming apparatus based on a predefined conversion table;
Another communication step of transmitting the command sequence converted in the conversion step to the image forming apparatus ;
An interface method comprising: The control command interface method of claim 6, characterized in that it comprises a command to be issued as a trigger for actually operating the front Symbol feeding paper discharge means. Wherein the control command, whether the sheet feeding operation in the sheet discharge feeding means, the presence or absence of the paper discharge operation, the interface method according to claim 6 or 7, wherein the command is a command that includes a designation of whether the scanning operation.

Images