RU2313821C2 - Device for providing images, recording device, recording system and method for controlling these - Google Patents

Abstract

FIELD: systems and methods for direct printing.

SUBSTANCE: in recording system, wherein digital photo-camera and printer are connected directly through data transfer interface, and image data are transferred from digital photo-camera to printer and recorded, it is determined, whether predetermined status information has been received during predetermined time period after digital photo-camera outputted predetermined command to printer. If it is determined, that predetermined status information is not received, status is determined as status supposed on basis of normal process, and process is continued. To confirm printer status, digital photo-camera requests printer status information, and receives printer status on basis of status information returned in response to the request.

EFFECT: absence of conflicts during exchange of signals between recording device and image providing device.

5 cl, 16 dwg

Description

FIELD OF THE INVENTION

The present invention relates to an image supply device, for example a digital camera, a recording device, a recording system, and a method for controlling them.

State of the art

In recent years, digital cameras (image sensing devices) that can receive images and convert them to digital image data through simple operations have become widespread. When the image received by the camera is printed and used as a photo, usually the received digital image data is temporarily downloaded from the digital camera to the PC (computer), image processing is performed on the PC, and the processed image data is transferred from the PC to the color printer, and thus printed picture.

On the contrary, for example, a color printing system that allows a digital camera to directly transfer digital image data to a color printer without the intervention of a PC and can print them, the so-called direct photo printer (PFP), in which a memory card that is installed in a digital camera and stores the received images can be directly installed in a color printer, and received images stored in a memory card that have recently been developed can be printed.

In particular, for direct transfer of image data from a digital camera to a printer and printing of image data, there was a need for standardization - specifications of the interface between each manufacturer’s digital camera and printer, operation method, etc. One standardization proposal is guidance on the implementation of NGN (direct printing systems).

However, a printer that directly receives image data from a digital camera and prints an image can also receive print data not only from a digital camera, but also from a PC, etc. For this reason, the response to a command from a digital camera may be delayed due to a print request from a PC when performing the preliminary procedure for receiving image data between the printer and the digital camera. For example, when a digital camera issues a print start request, which the printer receives, the status expressing the possibility of receiving the next command changes from “true” to “false” and the camera receives a notification about this status. If, for example, a PC issues a print request at the same time, the printer cannot quickly notify the camera of a status change. During this period, the camera can determine that the next command can also be received by the printer, and issue a command to the printer, even though the printer is in a busy state.

Disclosure of invention

The present invention relies on the consideration of the above situation and provides an image supply device which, when copying a response using a procedure determined in advance between the image supply device and the recording device, is not received from the recording device, determines that the status of the recording device is a status assumed based on normal procedure, and decides on subsequent processing procedures, the recording device, the recording system and how to manage them.

According to the present invention, there is provided an image supply device used in a recording system in which an image supply device and a recording device are directly connected by a data transmission interface, and image data is transmitted from an image supply device to a recording device and recorded, characterized in that it comprises: receiving means receiving status information from the recording device; determination means for determining whether the reception means has received predetermined status information from the recording device within a predetermined period of time after the image supply device has issued a predetermined command to the recording device; and processing means for, in the case where the determining means determines that no predetermined status information has been received, determining the status as a status assumed based on a normal process, and to continue the process.

According to the present invention, there is provided a recording device used in a recording system in which an image supply device and a recording device communicate with each other via a data transmission interface, image data is transmitted from an image supply device to a recording device and recorded, characterized in that it comprises: means issuing commands for issuing a predetermined command to the image feeder; receiving means for receiving a signal from the image pickup device after the command issuing command has issued a predetermined command; determination means for determining whether the signal received by the reception means is a response corresponding to a predetermined command; and control means for controlling timing of issuing the next command to the image pickup device when the determining means determined that the signal is not a response corresponding to a predetermined command.

Other features and advantages of the present invention will be apparent from the following description, taken in conjunction with the accompanying drawings, provided with an end-to-end notation.

Brief Description of the Drawings

The accompanying drawings, which are included in and constitute part of the description of the invention, illustrate embodiments of the invention and together with the descriptions serve to explain the principle of the invention.

Figure 1 is a schematic perspective view of a PFP printer according to an embodiment of the present invention.

Figure 2 is a schematic view of a control panel of a PFP printer according to an embodiment.

Figure 3 - block diagram of the device of the main part associated with the control of the printer PFP according to a variant implementation.

4 is a block diagram of a DSC device according to an embodiment.

FIG. 5 is a view for explaining a connection between a PFP printer and a digital camera according to an embodiment.

6 is a diagram of the exchange of commands between the printer PFP and DSC in the printing system according to a variant implementation.

7 is an example of a print start command issued by a DSC according to an embodiment.

8A and 8B are diagrams explaining JobStatus and DeviceStatus according to an embodiment.

FIG. 9 is a flowchart of a printing resumption process in a DSC according to a first embodiment. FIG.

Figure 10 is a logical block diagram of a process in a DSC according to a third embodiment.

11 is a logical block diagram of a process that accompanies the action of a button to continue printing in a DSC according to a fourth embodiment.

12 is a flowchart of a process accompanying a button for interrupting printing in a DSC according to a fifth embodiment.

FIG. 13 is a flowchart of a process in a DSC according to a fifth embodiment. FIG.

FIG. 14 is a flowchart of a process in a PFP printer according to a sixth embodiment. FIG.

FIG. 15 is a flowchart of another process in a PFP printer according to a sixth embodiment. FIG.

The implementation of the invention

Preferred embodiments of the present invention are described in more detail below with reference to the accompanying drawings.

FIG. 1 is a schematic perspective view of a direct photo printer 1000 (hereinafter referred to as a PFP printer) according to an embodiment of the present invention. The PFP 1000 printer has a function of receiving data from a host computer (PC) and printing data as a normal PC printer and a function of directly reading and printing image data stored in an information medium, such as a memory card, or receiving image data from a digital camera and printing data.

According to figure 1, the main body forming the housing of the printer PFP 1000 according to a variant implementation, has as an external part the lower part 1001, the upper part 1002, the access cover 1003 and the output tray 1004. The lower part 1001 forms the lower half of the printer PFP 1000, and the upper part 1002 forms the upper half of the main body. These parts together form a hollow structure having a free space in which the mechanisms (described below) are located. Holes are formed in the upper and front surfaces of the main body. One end of the output tray 1004 is rotatably held on the lower part 1001, and the rotation of the tray 1004 opens / closes an opening formed in the front surface of the lower part 1001. During the printing operation, the output tray 1004 is rotated to the front surface side to open the opening. The printed sheets may exit the opening and stacked sequentially on the output tray 1004. Two auxiliary trays 1004a and 1004b are placed in the output tray 1004. If necessary, the auxiliary trays can be pulled out to increase / decrease the load area of the printed sheets in three stages.

One end of the access cover 1003 is rotatably held on the upper part 1002, which makes it possible to open / close an opening formed in the upper surface. By opening the access cover 1003, you can replace the print head cartridge (not shown), ink (not shown), and the like, located in the main body. Although not shown, when opening / closing the access cover 1003, a protrusion formed on the rear surface of the access cover 1003 rotates the opening / closing lever of the cover. The open / closed state of the access cover 1003 can be detected by detecting a pivoting position of the lever using a micro switch or the like.

On the upper surface of the upper part 1002 is a power button 1005. A control panel 1010, which includes a liquid crystal display unit 1006, various pushbuttons, and the like, is provided on the right side of the upper part 1002. The design of the control panel 1010 will be described in more detail below with reference to FIG. 2. Reference numeral 1007 denotes an auto-feeder that automatically feeds a printed sheet to the main body of the device. Reference numeral 1008 denotes a paper thickness selection lever that is used to adjust the clearance between the print head and the print sheet. Reference numeral 1009 denotes a slot for a card that receives an adapter capable of receiving a memory card. Image data stored on a memory card can be directly read and printed through this adapter. Examples of a memory card (PC) are a compact flash ™ memory card, a smart media card, and a memory line. Reference numeral 1011 denotes a viewing device (liquid crystal display unit) that is capable of detaching from the main body of the PFP 1000 printer, and is used to display an image for one frame, an index image, and the like when a user wants to search for images stored in a PC card on the subject of the image to be printed. 1012 denotes a USB connector that is used to connect a digital camera (described later). In addition, another USB port for connecting a personal computer (PC) is provided on the rear surface of the PFP 1000 printer.

2 is a schematic view of a control panel 1010 of a PFP printer 1000 according to an embodiment.

2, the liquid crystal display unit 1006 displays menu items for various data settings associated with items printed on the right and left sides of the unit 1006. The items displayed on the liquid crystal display unit 1006 include, for example, a first number or a specified frame number the photograph to be printed (start / specified), the final number of the photograph to be completed (end), the number of copies to be printed (copy counter), the type of paper (printed sheet), we use printing (type of paper), setting the number of photographs to be printed on one sheet of paper (configuration), indicating print quality (quality), indicating whether to print the date of photographing (date printing), indicating whether to print the photo after correction ( image correction), display of the number of sheets of paper required for printing (paper counter), etc. The user selects or indicates these items using the 2001 cursor buttons. Position 2002 indicates a mode select button. Each time you press the mode selection button 2002, the print type (index print, print all frames, print one frame, etc.) can be switched, and the corresponding LED 2003 lights up in accordance with the selected print type. 2004 refers to a maintenance button that is used to perform maintenance on the printer, such as cleaning the print head. Position 2005 denotes a print start button that is pressed to indicate the start of printing or assigning a service setting. Position 2006 denotes a print cancel button that is pressed to cancel printing or service.

An apparatus for a main part associated with controlling a printer of the PFP 1000 according to an embodiment is described below with reference to FIG. 3. In Fig. 3, parts common with the above-mentioned drawings are denoted by the same positions and their description is omitted.

3, reference numeral 3000 denotes a controller (control board). Position 3001 denotes SIS (specialized LSI). Reference numeral 3002 denotes a DSP (Digital Signal Processor), which includes a CPU and performs various control processes (described below) and image processing, for example, converting a luminance signal (RGB) to a density signal (CMYK), scaling, gamma conversion, and error correction. 3003 denotes a memory having program memory 3003a in which the control program for the CPU DSP 3002 is stored, the RAM area has a memory area acting as a work area in which image data is stored, etc. 3004 denotes a printer mechanism. In one embodiment, the printer is equipped with an ink jet printer mechanism that prints a color image using a combination of color inks. Reference numeral 3005 denotes a USB connector serving as a port for connecting a digital camera (DSC) 3012. Reference numeral 3006 denotes a connector for connecting a viewing device 1011. 3008 denotes a USB hub (USB HUB). When the PFP 1000 printer performs printing based on image data from a PC 3010, the USB hub 3008 allows data to pass from the PC 3010 through itself and outputs the data to the printer engine 3004 via USB 3021. The connected PC 3010 can directly exchange data and signals with the printer engine 3004 and print (function like a regular PC printer). Reference numeral 3009 denotes a power source connector that supplies a DC voltage converted from commercial AC power from a power source 3019. PC 3010 is a regular personal computer. Reference numeral 3011 denotes the aforementioned memory card (PC card); and reference numeral 3012 denotes a digital camera (also referred to as a DSC: digital camera).

Note that the signal exchange between the controller 3000 and the printer mechanism 3004 is through the USS 3021 or the IEEE1284 3022 bus.

Figure 4 shows a block diagram of a DSC device (digital camera) 3012.

In figure 4, the position 3100 denotes the CPU that controls the entire DSC 3012; and position 3101 denotes a ROM in which the processing sequence (control program) of the CPU 3100 is stored. Position 3102 denotes a RAM that is used as a work area for the CPU 3100; and reference numeral 3103 denotes a switching group that is used to perform various operations. Switching group 3103 includes various switches, cursor buttons, etc. Position 2700 denotes a liquid crystal display unit that is used to display the image currently being photographed or the received / stored image and to display the menu for various settings of the DSC 3012. Position 3105 denotes an optical unit containing mainly a lens and its drive system. Reference numeral 3106 denotes a CCD element; and reference numeral 3107 denotes a driver that drives and controls the optical unit 3105 under the control of the CPU 3100. Reference numeral 3108 denotes a connector for connecting an information medium 3109 (compact flash ™ memory cards, smart media cards, etc.); and reference numeral 3110 denotes a USB interface (USB slave side) for connecting a PC or PFP 1000 printer according to an embodiment.

FIG. 5 is a view for explaining a connection between the PFP printer 1000 and the DSC 3012 according to an embodiment. Parts common to the above drawings are indicated by the same reference numerals and their description is omitted.

5, cable 5000 includes a connector 5001 connected to connector 1012 of the PFP 1000 printer, and connector 5002 for connecting to connector 5003 of digital camera 3012. Digital camera 3012 can output image data stored in the internal memory (memory card) through connector 5003. The digital camera 3012 may have various designs, for example, a design including a memory as a storage medium, and a design having a slot for inserting a removable memory. The PFP printer 1000 and the digital camera 3012 are connected by a cable 5000 shown in FIG. 5, and the image data from the digital camera 3012 can directly go to the PFP 1000 printer and printed by the PFP 1000 printer.

Examples of operation of a printing system according to an embodiment based on the above construction will be described as embodiments.

[First Embodiment]

Let us describe in general terms the operation of a printing system including a DPC 3012 and a PFP 1000 printer based on the above-described device. In the printing system according to the first embodiment, the DSC 3012 and the printer PFP 1000 can operate in accordance with the specifications of the NGN (direct printing system).

FIG. 6 is a diagram for explaining a sequence in which a DSC 3012 issues a print request to a PFP printer 1000 for printing in a printing system according to a first embodiment.

This processing sequence is performed when the printer PFP 1000 and DSC 3012 are connected by cable 5000 and it is confirmed that they are consistent with the specifications of the NGN. The DSC 3012 transmits a "ConfigurePrintService" to the PFP 1000 printer to obtain the status of the PFP 1000 printer (600). In response, the PFP 1000 printer notifies the DSC 3012 of the current state (in this case, the "idle" state) of the PFP 1000 (601) printer. DSC 3012 finds out the capabilities of the PFP 1000 printer (602) and issues a print start request (StartJob) corresponding to the capabilities (603). A print start request is issued provided that “newJobOK” (FIG. 8B) in the status information (described below) from the PFP printer 1000 is “true” at 601.

In response to the request to start printing, the PFP 1000 printer requests the information of the DSC file 3012 based on the file ID of the image data to be printed (604). File information contains information elements such as file capacity (file size), the presence / absence of a thumbnail, and file attributes. When the printer PFP 1000 receives the file information and determines that the file can be processed, the printer PFP 1000 requests the file DSC 3012 (605). DPC 3012 transmits image data of the requested file to DSC 3012. After that, when the PFP 1000 starts the printing process, the PFP 1000 transmits status information representing "Printing" to the DSC 3012 via "NotifyDeviceStatus" ("notify the status device ”) at 606. At the end of the printing process of one page, the PFP 1000 printer notifies the DSC 3012 of the completion of the printing process by means of“ NotifyJobStatus ”607 (“ notify about job status ”) at the beginning of processing the next page. To print only one page, the PFP 1000 printer notifies the DSC 3012 of the "idle" state by means of a "NotifyDeviceStatus" 608 at the end of printing one requested page. To print N images by placing the plurality of (N) images on one page, the PFP 1000 sends a “NotifyJobStatus” 607 to the DSC 3012 each time after the N images are printed. The timing of the delivery of “NotifyJobStatus” and “NotifyDeviceStatus” and the procedure for obtaining image data in the first embodiment are illustrative, and different cases can be considered depending on the product specification.

The printing process involves the case when the ID of the image data files to be printed are placed and immediately transmitted in the print start request (StartJob) from the DSC 3012 for printing, and the case where only the file ID for the DPOF file [Digital Print Order Format], used for the usual development of photographs, it is placed in the print start request (StartJob) from the DSP 3012 and transferred to the PFP 1000 printer, and the PFP 1000 printer interprets the DPOF file, receives the file ID of the necessary image data and prints them.

7 shows an example of a print start request issued by the DSC 3012 to the PFP 1000 printer.

In FIG. 7, reference numeral 720 denotes a setting (jobConfig), a print job and reference numeral 721 denotes print information (printInfo).

Let us explain the setting 720. Position 700 (quality) denotes print quality, for example, “normal” or “high”. Position 701 (paperSize) indicates the size of the paper, and position 702 (paperType) indicates the type of paper, for example, “plain paper”, “photo paper” or “inkjet paper”. 703 (fileType) denotes the type of image file to be printed, and when, for example, DPOF is used, a type representing DPOF is indicated by file type 703. Position 704 (datePrint) indicates whether to print the date, position 705 (fileNamePrint) indicates whether to print the file name, position 706 (imageOptimize) indicates whether to optimize the image, position 707 (fixedSize) indicates whether to print a fixed size , and the position 708 (cropping) indicates whether to print the specified portion of the image.

Information 721 print contains the file ID 709 (fileId) and information 710 date (date).

FIGS. 8A and 8B are diagrams explaining information items contained in JobStatus and DeviceStatus described above. JobStatus (FIG. 8A) and DeviceStatus (FIG. 8B) are transmitted from the PFP 1000 printer to the DSC 3012. The DSC 3012 can request the PFP 1000 to transmit these items of information with arbitrary timing.

8A, "prtPID", "ImagePath", and "copyID" become effective when printing a DPOF file is indicated. "prtPID" is the identification information (ID) of the print section indicated by the DPOF file. "ImagePath" is path information for specifying an image file designated by a DPOF file. "copyID" indicates the number of copies to print after specifying the printing of the set of copies. When printing based on a DPOF file, the DSC 3012 describes the "fileID" of the DPOF file in a print start request (StartJob) and transmits a print start request to the PFP 1000 printer. In response, the PFP 1000 printer can start printing the DPOF file. The printer PFP 1000 receives the DPOF file based on the "fileID" of the DPOF file, executes "GetFileID" and indicates the "fileID" of the image file specified in the DPOF file. The printer PFP 1000 requests the image file DSC 3012 and receives the image data. As a result, you can print the image specified in the DPOF file. When printing based on a DPOF file, the PFP 1000 printer notifies the DSC 3012 via “NotifyJobStatus” for “prtPID”, “ImagePath” and “copyID” representing the print progress.

When the printing process resumes after interruption for one reason or another while the DPOF file is printing, the printing process resumes from the beginning of the page on which the printing process was interrupted.

"progress" represents the current page (N / T) while printing the upcoming number of pages. N represents the current print page, and T represents the total number of print pages to be printed. "imagePrinted" represents the number of printed images.

Now explain DeviceStatus (pigv).

"dpsPrintServiceStatus" indicates the status of the PFP 1000 printer and is transmitted to the DSC 3012 from the PFP 1000 printer. "dpsPrintServiceStatus" includes an idle state, a print state, and a pause state. "jobEndReason" indicates the final state of the printing process and is transmitted to the DSC 3012 upon completion of printing of the final page. "errorStatus" represents the error state and is transmitted after the error is generated. "errorReason" means the cause of the error and is transmitted in conjunction with "errorStatus".

“disconnectEnable” means that printing is possible even if the USB cable 5000 is disconnected from the PFP 1000 printer. The PFP 1000 printer notifies the DSC 3012 of “disconnectEnable”. "capabilityChanged" means that the capabilities of the PFP 1000 printer have changed, and is transmitted to the DSC 3012. "newJobOK" means that the PFP 1000 printer can accept a print request, and is transmitted to the DSC 3012.

FIG. 9 is a flowchart of a printing resumption process in a DSC 3012 according to a first embodiment. The program that performs this process is stored in ROM 3101, and the CPU 3100 performs the control process in accordance with the program for implementing the process.

In this process, the printing operation is interrupted when, for example, the cable 5000 is disconnected during the printing operation. After that, the reconnection of the NGN is established, the print button of the DSC 3012 is pressed, and the printer PFP 1000 receives a command to resume the print operation. Then, the PFP 1000 printer resumes printing.

This process assumes that the interruption of the printing process on the PFP 1000 printer and the interruption of the printing process on the DSP 3012 are recognized by the PFP 1000 and DPS 3012 printer.

At step S1, it is determined whether the DSC 3012 and the PFP printer 1000 are physically connected using a cable 5000, and the like. and whether the reconnection of the NGN is established. If the connection is established, the process proceeds to step S2. If the DSC 3012 indicates the resumption of printing, then a determination is made whether the printing process has been interrupted. If the printing process has not been interrupted, the process advances to step S3 for the normal printing process, for example, the process of starting the printing process again in accordance with the printing instruction.

If the printing process has been interrupted, the process proceeds to step S4. A determination is made whether the PFP 1000 printer that re-established the connection is the same model (the same <dpsVersion> and <productName>), the model of the same manufacturer (<productName>), or the model of that vendor (<vendorName>) as PFP 1000 printer, which interrupted the previous printing process. In this procedure, the PFP 1000 printer model is determined based on the content transmitted by the PFP 1000 in response to a "ConfigurePrintService" issued by the DSC 3012. When the same PFP printer is reconnected, there is no problem. Even for a different printer model, if the manufacturer or supplier of the printer is the same and the re-printing process according to the first embodiment is possible based on the design of the manufacturer or supplier, it can be determined that printing can be resumed and the process proceeds to the next process S6. If the answer is NO in step S4, the process proceeds to step S5 to determine that the printing process cannot continue, and display the message on the display unit 2700 of the DSC 3012. If necessary, the PI (user menu window) displayed on the display unit 2700 can be changed.

If it is determined in step S4 that the reconnected device is a compatible model, the process proceeds to step S6 to determine whether the printing process is performed using the DPOF file. If the answer is YES at step S6, the process proceeds to step S7 to transfer the file ID for the DPOF file to the printer PFP 1000. In this case, the above-described "prtPID", "ImagePath" and "copyID" are transmitted together with the file ID for the DPOF file, thereby indicating that the file is subject to a renewed printing process using the DPOF file.

If the printing process is not performed using the DPOF file in step S6, i.e. each image file must be specified and printed, the file ID for image files, with the exception of the printed image files among the file ID for image files to be printed, are transferred immediately to the PFP 1000 printer for printing. Note that as a print resume instruction, a print button is pressed among the operation buttons of the DSC 3012 to send “StartJob” from the DSC 3012 to the PFP 1000 printer, and the printing process is resumed.

The PFP printer 1000 notifies the DSC 3012 that it has finished printing each page by means of "jobStatus" (signifying the start of the next page) sent from the PFP 1000 at the beginning of the next page, or "jobEndReason" contained in the "deviceStatus" for the destination page. Therefore, DSC 3012 can confirm the number of printed images. Whether the printing process was interrupted, it can be determined based on whether the number of images indicated in the print instruction was printed when the images are printed one after another, or from the path ("prtPID", "ImagePath" and "copyID") in the DPOF file, or whether the printing process is completed when the printing process is based on a DPOF file.

When printing one image per page, the number of sheets of printing paper is the same as the number of images. When a collection of (N) images is placed and printed on one sheet of paper, the number of images to be printed does not coincide with the number of sheets of paper to be printed. DSC 3012 should take the number of sheets of paper for printing and the amount of image data matching with each other in accordance with the print mode.

[Second Embodiment]

When the date stamp of <datePrint> 704 is indicated in <jobConfig> 720 in Fig. 7, the <date> 710 contained in <printInfo> 721 is printed. When the date stamp of <datePrint> 704 is not specified in <jobConfig> 720, the date data is ignored and not printed even if <date> 710 is contained in <printInfo> 721.

This can increase the degree of freedom of the data contained in <printInfo> 721. The startJob command can be created, for example, by directly transferring image data and a list of dates that are used by another job to <printInfo> 721.

[Third Embodiment]

10 is a flowchart for explaining a process in a printing system according to a third embodiment of the present invention.

In the third embodiment, when the DSC 3012 issues any command to the printer PFP 1000 and the status of the printer PFP 1000 changes, the printer PFP 1000 notifies the DSC 3012 the status through the above "NotifyDeviceStatus". However, when the state of the PFP 1000 printer does not change or the response is delayed, the DSC 3012 determines (evaluates) that the previously issued command has led to the alleged change in the status of the PFP 1000 printer and performs the corresponding process. To confirm the status, the printer PFP 1000 DPC 3012 issues "GetDeviceStatus" to the printer PFP 1000, receives the status of the printer PFP 1000 and performs the process corresponding to the received printer status.

An example of this process will be explained with reference to the flowchart shown in FIG. 10.

In step S10, the print start request “StartJob” is sent to the PFP 1000 printer. The process proceeds to step S11 to determine if a predetermined status response “NotifyDeviceStatus” is received from the PFP 1000. If the PFP 1000 printer is a type of product that can accept only one print job, newJobOK from NotifyDeviceStatus, indicating that the PFP 1000 printer can accept the next print job, should be set to false after issuing the print start request "startJob" to the PFP 1000 printer If a normal response arrives at step S11 (newJobOK is false), the process advances to step S12 to wait until “newJobOK” changes to “true”.

After that, the normal printing process is performed, consisting in issuing the next command or outputting image data, etc. as requested by the PFP 1000 printer.

At step S13, a determination is made whether "NotExecuted" is received, expressing that the "StartJob" cannot be executed. If “NotExecuted” is not received, the process proceeds to step S20 to issue “GetDeviceStatus” to the printer PFP 1000 and obtain the current status of the printer PFP 1000. If this status opens the reason for the impossibility of executing the instruction and “StartJob” can be issued again, the message is therefore is displayed on the PI of the display unit 2700 of the DSC 3012. After that, if the user indicates the re-issuance of the instruction using the button 3103, the process proceeds from step S21 to step S22 to re-issue the “StartJob” instruction to the printer PFP 1000 that has not been executed. If no re-issuance instruction is received in step S21, the process proceeds from step S21 to step S19.

If “NotExecuted” is not received in step S13, then the process proceeds to step S14 to determine whether “NotSupported” has been received. If "NotSupported" is accepted, the process advances to step S15. In this case, the previously issued “StartJob” is not supported by the PFP 1000 printer and, for example, unsupported elements (impossible to specify) are displayed on the PI of the display unit 2700 to represent that the print instruction is not supported by the PFP 1000 printer.

The meaning of the lack of support for the StartJob instruction includes the case when the PFP 1000 printer does not support the StartJob instruction itself, and also the case when the PFP 1000 printer supports the StartJob instruction itself but does not support the currently issued The StartJob instruction itself is an unsupported paper size or paper type. In this case, the PI CFA 3012 is rebuilt so as to prohibit the selection of the wrong paper size or paper type (elements to be adjusted for the printing operation), by analogy with the above example. This may reduce the likelihood of re-receiving “NotSupported” when the “StartJob” instruction is repeated on the PFP 1000 printer. Note that upon receiving “NotSupported”, a process may be performed, for example, confirming the paper size or paper type supported by the PFP 1000 printer.

If "NotSupported" is not received on the PFP 1000 printer, the process proceeds to step S11 '. At this point, it is assumed that the content of the response is essentially “OK”. If a predetermined status response is received in step S11 ′, the process proceeds to step S12 to continue normal operation. If no predetermined status information is obtained in step S11 ′, the process proceeds to step S16 to determine whether to continue operation as normal operation. This can be displayed using the aforementioned PI to allow the user to select normal operation. If the process proceeds to normal operation, then the process proceeds to step S12. If the user does not enter any instructions and the process does not proceed to normal operation, the process proceeds to step S17 to request the status of the PFP 1000 printer using "GetDeviceStatus". The process proceeds to step S18, and the status of the PFP printer 1000 is obtained, and if the status is normal, it is determined that this status is assumed to be normal, and the process proceeds to step S12. If a different status is obtained, the process advances to step S19 to execute the process corresponding to the received status.

The reason the unexpected “NotExecuted” was sent back as an answer in step S13 is because, for example, the PC 3010 is connected to the PFP 1000 printer, the print instruction from the PC 3010 was received by the PFP 1000 printer almost at the same time as the print start request from the DSP 3012, and the printing process of printing data from the PC 3010 begins. That is, since the DPC 3012 recognizes "newJobOK" = "true" in advance based on NotifyDeviceStatus issued by the PFP 1000 printer, the DSC 3012 issues a "StartJob" command. However, as soon as the "StartJob" command is issued, "newJobOK" = "false" is set and the PFP 1000 printer sends a "NotExecuted" response. The DSC 3012, which recognized "newJobOK" = "true", receives an unexpected "NotExecuted" response from the PFP printer 1000. The reason that the predetermined status information was received in step S11 is because, for example, the PFP printer 1000 is a product capable of accepting a set of print jobs, and even after the print request "StartJob" is accepted, the "newJobOK" from "DeviceStatus" remains invariably equal to "true", and thus, the PFP 1000 does not issue "NotifyDeviceStatus" on the DSC 3012 In addition, in this case, the DSC 3012 reliably operates on the assumption that "newJobOK" set to false until the state of the PFP 1000 printer is confirmed by GetDeviceStatus (due to the possibility of a delay in issuing NotifyDeviceStatus representing "newJobOK" = false for any reason).

The above description is based on the assumption that even when the command from the DPC 3012 and the command from the printer PFP 1000 are issued almost simultaneously, both commands are effective. However, there may also be a direct printing specification: "from almost simultaneously issued commands, the command from the DPC 3012 is preferably processed, and the issuance of the command from the printer PFP 1000 is ignored and rejected." In this case, the verification content in step S11 is “has the command issued by the PFP printer 1000 been received?”. If the answer is YES at step S11, the process proceeds to step S13 through the step (not shown) of ignoring the command from the printer PFP 1000; if no command is received from the printer 1000, the process proceeds immediately to step S13.

In the aforementioned direct printing specification, the rejected PFP 1000 printer command can be re-issued by the PFP 1000 printer. For example, consider the case where the print instruction from the PC 3010 arrives almost simultaneously with the “StartJob” from the DSC 3012 and the printing process for the print data from the PC 3010 begins. DSC 3012, which previously recognized "newJobOK" = "true" by NotifyDeviceStatus issued by the printer PFP 1000, gives the instruction "StartJob" in advance. Almost at the same time, the PFP 1000 printer, which starts the printing process for print data from PC 3010, changes "newJobOK" = "false". In order to notify the DSP 3012 of this, the PFP printer 1000 issues a NotifyDeviceStatus instruction to the DSC 3012. However, the NotifyDeviceStatus instruction issued by the PFP printer 1000 is rejected, and the StartJob instruction issued by the DSC 3012 is preferably processed. Since the PFP 1000 printer has already changed “newJobOK” to “false,” it sends back “NotExecuted” in response to the “StartJob” instruction. At this time, the PFP 1000 printer must re-issue the “NotifyDeviceStatus” instruction to notify the DSC 3012 of “newJobOK” = “false”. At this time, if the DSC 3012 issues the following command, instructions (commands) are again issued by the two devices almost simultaneously.

Basically, a situation where two devices issue commands almost simultaneously and one of them is rejected can occur when the criteria statuses used to issue commands from two devices are different. In this case, the direct printing process becomes very unstable and is in a dangerous state. Therefore, a situation in which two devices issue commands almost at the same time is preferably avoided as much as possible. To this end, for example, when the DSC 3012 detects a “command issued by the PFP printer 1000” in step S11, the issuing of the “GetDeviceStatus” instruction may be disabled in step S20 or S17 for a predetermined period of time, pending a command from the PFP printer 1000.

In addition, the PFP 1000 printer as a direct printing partner can be set to prohibit issuing a command from the PFP 1000 printer for a predetermined period of time and wait for a command from the DSC 3012. If these predetermined prohibition periods are equal, then the commands will be issued almost simultaneously two devices after a predetermined period of time. Given this possibility, a predetermined period of time may not be fixed and may change intermittently and irregularly dynamically. Alternatively, the prohibition time period used when “command issuance by the printer PFP 1000 is not detected” in step S11 can be used until “command issuance by the printer PFP 1000 is detected” in step S11, and update when “command issuance by the printer PFP 1000 is detected "In step S11. As a way to change the timing of issuing commands, timing of the issuance may be determined in advance. To avoid the transition of two devices to the same timing, the timing can be changed according to a predetermined rule. For example, the timing change method can be set depending on the USB master or slave device. Alternatively, the DSC 3012 and the PFP printer 1000 may comprise means for generating random timing signals, and timing of the issuance of commands may be determined in accordance with the timing signals, respectively. As described above, the printer PFP 1000 can also be brought into a state where issuing commands from the printer PFP 1000 is prohibited for a predetermined period of time, which reduces the possibility of almost simultaneously issuing commands from two devices. Various modifications of the above may also be applied.

[Fourth Embodiment]

We describe the process of continuing printing with the DSC 3012 in the printing system according to the fourth embodiment and the process of interrupting printing. In addition, in this case, the printing system, DSC 3012 and the printer PFP 1000 are arranged in the same way as described above, and their description will be omitted.

11 shows a logical flowchart of a process for continuing printing that is performed when the printing process in the DSC 3012 according to the fourth embodiment is interrupted and then executed by pressing the print button, which indicates the start of printing.

At step S110, a determination is made whether the print button was pressed among the operation buttons 3103 of the DSC 3012. If the answer NO is received at step S110, the process proceeds to step S111 to perform another process, for example, a process corresponding to the pressed button or waiting for instructions associated with the button . If the print button has been pressed, the process advances to step S112. A GetDeviceStatus is issued to the PFP 1000 printer to request status information of the PFP 1000 printer and receive status information transmitted from the PFP 1000 printer in response to the request. The process advances to step S113 to determine, based on the received information, whether the status of the PFP 1000 printer is “pause”. If the answer is YES at step S113, the process proceeds to step S114 to determine if an error occurred with the issuance of a “warning” (for example, the cable is disconnected) or there are no errors. If the answer YES is received at step S114, the resumption of the printing process is determined as possible (since the status was received from the printer PFP 1000). The process advances to step S115 to instruct the printer PFP 1000 to resume the printing process (transmission "ContinueJob").

If the pause state is not set in step S113 or another error does not occur in step S114, then the resumption of the printing process is determined to be impossible and a corresponding message is displayed on the PI of the display unit 2700. In this case, for example, a message is displayed on the PI of the display unit 2700 notifying the user that the printing process cannot be resumed and / or the print button is locked. Useless pressing of the print button by the user can be avoided by obtaining the status of the printer PFP 1000 before pressing the print button determined in step S110, and notifying the user whether the print button is valid.

12 is a flowchart of a printing interruption process that is performed when a print interruption button is pressed, which indicates an interruption of the printing process in the DSC 3012 according to the fourth embodiment.

At step S121, a determination is made whether the interrupt button was pressed among the operation buttons 3102 of the DSC 3012. If the answer NO is received at step S121, the process proceeds to step S122 to execute another process, for example, a process corresponding to the pressed button or waiting for instructions associated with the button . If the interrupt button has been indicated (pressed), the process proceeds to step S123. A GetDeviceStatus is issued to the PFP 1000 printer to request current PFP 1000 printer status information in response to the request. The process advances to step S124 to determine, based on the received status information, whether the status of the PFP 1000 printer is “pause”. If the answer is YES at step S124, the process proceeds to step S126; if NO, go to step S125 to determine if printing is progressing. If the answer YES is received at step S125, then the interruption of the printing process is determined as possible and the process proceeds to step S126 to instruct the PFP printer 1000 to interrupt the printing process (transmission "AbortJob").

If the answer NO is received at step S125, then the interruption of the printing process is determined to be impossible and a corresponding message is displayed on the PI of the display unit 2700. In this case, for example, a message is displayed on the display unit 2700 notifying the user that the print cannot be interrupted and / or the interrupt button is locked. Useless pressing of the interrupt button by the user can be avoided by obtaining the status of the PFP 1000 printer before pressing the interrupt button determined in step S121, and notifying the user whether the interrupt button is active.

[Fifth Embodiment]

13 is a flowchart for explaining a process in a printing system according to a fifth embodiment of the present invention. The program that performs this process is stored in ROM 3101. In addition, in the fifth embodiment, the DSC 3012 and the printer PFP 1000 are arranged in the same way as in the above embodiments, and their description will be omitted.

In the fifth embodiment, when the DSC 3012 issues a command to the printer PFP 1000, the DSC 3012 is notified of the response of the printer PFP 1000 to the command. If the response includes unexpected content, then the DSC 3012 issues “GetDeviceStatus” to the PFP printer 1000 to obtain the current state of the PFP 1000 printer. When the received status is the status assumed based on the command issued immediately before receipt and the response content is normal process. If the status is not intended, then the process corresponding to the status is performed.

At step S50, the “StartJob” instruction is issued to the PFP 1000 printer as a print start request. The process advances to step S51, and if a response to the print start request is received from the printer PFP 1000, the contents are determined. If the content includes “NotExecuted”, expressing that the “StartJob” instruction cannot be executed, the process proceeds to step S52 to issue the “GetDeviceStatus” instruction to the PFP printer 1000. In step S53, the DSC 3012 awaits a response from the PFP printer to the instruction 1000 and receives the current status of the PFP 1000 printer. At step S54, a reason is analyzed for why the print start instruction was not executed. If the reason is found, the process proceeds to step S55 to change the display of the UI and wait for the user to enter the instruction using the operation button 3103. If, at step S56, a print start request is received, the process proceeds to step S50 to perform the above process. Note that if a command other than the print request is indicated in step S50, the corresponding process is implemented, but this process is not shown in FIG.

If in step S51, the content of the response is not “NotExecuted”, then the process proceeds to step S57 to determine whether the content is “NotSupported”. If the content is “NotSupported,” then the process advances to step S58. Since the previously issued “StartJob” instruction is not supported by the PFP 1000 printer, for example, (impossible indication) is displayed on the PI of the display unit 2700 to represent that the command is not supported by the PFP 1000 printer. The meaning of the lack of support for the “StartJob” instruction includes the case when the PFP 1000 printer does not support the StartJob instruction per se, and also the case when the PFP 1000 printer does not support the StartJob instruction itself but does not support the StartJob instruction issued by itself at the moment, because the unsupported my paper size or paper type. In this case, unsupported printing conditions can be eliminated by rebuilding the PI so as to prohibit the selection of the wrong paper size or paper type, by analogy with the above example. This may reduce the possibility of retrieving "NotSupported" from the PFP 1000 printer when issuing the "StartJob" instruction again. At this time, a process may occur, for example, confirming the paper size or paper type supported by the PFP 1000 printer. After the PI has changed in this way, the process proceeds to step S55 to wait for the next instruction to be input, and proceeds to the corresponding process.

If it is determined in step S57 that the content of the response is not “NotSupported,” then the process proceeds to step S59. It is assumed that the answer is essentially “OK”. At step S59, it is determined whether a predetermined status message “NotifyDeviceStatus” has been received from the printer PFP 1000 within a predetermined period of time. Assume that the PFP 1000 printer accepts only one print job. If the "StartJob" instruction is issued as a print start request, then "newJobOK" from "NotifyDeviceStatus", which expresses that the PFP 1000 printer cannot accept the next print job, should be false. For this reason, if at step S59 a predetermined status response is received corresponding to the print start request, the process proceeds to step S63 to continue normal operation, after which the operation ends.

If at step S59 no predetermined status information is received for a predetermined period of time, the process proceeds to step S60 to issue “GetDeviceStatus” to the printer PFP 1000 and obtain the status of the printer PFP 1000. If at step S61 a response is received from the printer PFP 1000 , the process proceeds to step S62 to determine whether the received status is the expected status corresponding to the command issued immediately before receiving a response. If the answer is YES at step S62, the process advances to step S63 to complete the normal process. If an unexpected status is obtained, the process advances to step S64 to execute the process corresponding to the status.

An example of a “proposed status corresponding to a response” in the fifth embodiment is a status that means “printing” as a result of issuing “GetDeviceStatus” when “NotifyDeviceStatus” does not arrive within a predetermined period of time, although at step S50 it is issued request to start printing to receive "OK". In this case, the normal process may continue on the assumption that the issuance of "NotifyDeviceStatus" is delayed for any reason (for example, transferring an image file takes a lot of time). As another status in the fifth embodiment, in response to issuing "GetDeviceStatus", a status that does not mean "print" can be returned. In this case, different options are possible: the print start request was not processed normally for any reason, or the print was canceled due to conditions on the PFP 1000 printer within a very short time elapsed after the print start request was issued. These reasons should be combined with other status information (for example, error information) to determine the subsequent process. In addition, the simultaneous use of the configuration corresponding to the third embodiment can realize a more stable direct printing process.

In the fifth embodiment, the issuance timing request varies depending on the process on the image data supply side. In particular, the image supply device (camera) issues a predetermined command to the recording device (printer). After the image pickup device issues a predetermined command, it determines whether the signal received from the recorder is a response to the predetermined command. If the image pickup device determines that the signal is not a response to a predetermined command, the image pickup device changes the timing of the output when the next command is issued.

However, the present invention can also be applied to a recording device or device that receives image data. In particular, a recording device or device that receives image data provides a predetermined command to the image supply device. After the recording device or device issues a predetermined command, it determines whether the signal received from the image pickup device is a response to the predetermined command. If the recording device or device determines that the signal is not a response to a predetermined command, the recording device or device that receives the image data changes the timing of the next command.

[Sixth embodiment]

The above described embodiments mainly describe the processes in the DSC 3012. The sixth embodiment explains the process when the PFP 1000 receives image data from the DSC 3012. The equipment configuration in the sixth embodiment is the same as in the first embodiment, and its description will be omitted.

FIG. 14 is a flowchart of a process for acquiring image data on a PFP printer 1000 according to a sixth embodiment of the present invention. The program that performs this process is stored in program memory 3003a and runs under the control of DSP 3002.

This process begins with the DSC 3012 sending a print request ("StartJob") indicating the start of the printing process. In step S31, “GetFileInfo” is supplied to the DSC 3012 to request information about the image file required by the DSC 3012. In step S32, when the information (file size, attribute, etc.) for the image file comes from the DSC 3012, an element is obtained that is contained in information and expresses the capacity of the file. The process advances to step S33 to determine whether it is possible to receive the entire image file and process it immediately. This determination is made based, for example, on the free space memory capacity in the memory 3003 of the PFP 1000 printer. If it is determined that it is not possible to immediately receive all the image data, the process proceeds to step S34 to read the image file. The start address and reading volume are indicated for requesting partial image data of the image file. This is done using the "GetPartialFile". The DPC 3012 reads the specified partial image data from the image file in accordance with the start address and reading volume and transmits the partial image data to the PFP printer 1000. The PFP printer 1000, having received the partial image data in step S35, processes and prints the partial image data in step S36. The process proceeds to step S37 to determine whether all image data of the image file is printed. If the answer NO is received at step S37, the process returns to step S34 to request the next partial image data. This process is repeated until the entire image file indicated in step S32 is received and printed.

If it is determined in step S33 that the image data of the image file can be immediately received and processed, the process proceeds to step S38 to request all the data of the image file of the DSC 3012. In step S39, all image data of the image file sent from the DSC 3012 based on the request is received and are printed.

FIG. 15 is a flowchart for explaining another example of a process for acquiring image data on a PFP printer 1000 according to a sixth embodiment of the present invention. The program that performs this process is stored in program memory 3003a and is run by the DSP 3002.

This process begins when the DSC 3012 sends a print request ("StartJob") indicating the start of the printing process. In step S41, the DSC 3012 sends “GetFileInfo” to request information about the image file indicated by the DSC 3012. In step S42, if the image file information is sent from the DSC 3012, the process proceeds to step S43 to determine if the image file contains thumbnails (index images). If the image file contains thumbnails, the process advances to step S44 to determine whether index printing is indicated using the control unit 1010. If index printing is indicated, the process advances to step S45 to request data for a thumbnail image of the DSC 3012 (output “GetThumb”) and obtain data. The process proceeds to step S46 for performing index printing based on the obtained thumbnail image data.

If it is determined in step S43 that the image file does not contain thumbnails, or index printing is not indicated in step S44, the process proceeds to step S33 (Fig. 14) to perform the above image printing process.

Thus, according to the sixth embodiment, the amount of image data obtained at a time from the DSC 3012 can be changed and received from the DSC 3012 in accordance with the memory capacity and processing power of the PFP 1000 printer.

You may find in advance that the thumbnail image is already saved in the DSP 301 image file. When index printing is indicated on the PFP 1000 printer, the process of creating a thumbnail on the PFP 1000 printer can be omitted. This allows you to quickly print a thumbnail image (index image).

The present invention is also applicable to a system including a plurality of devices (for example, a host computer, an interface device, a reader and a printer) or a device (for example, a copy machine or fax machine) made in the form of a single device.

The objective of the present invention is also achieved when the storage medium (or recording medium) on which program codes are stored for implementing the functions of the above-described embodiments (processes carried out on the camera side and various printing processes carried out on the printer side) is supplied to a system or device and a computer (or CPU or SME) of a system or device reads and executes program codes stored on a storage medium. In this case, the program codes read from the information medium realize the functions of the above-described embodiments, and the information medium storing the program codes constitutes the present invention. The functions of the above embodiments are realized when the computer executes the read program codes. In addition, the present invention provides a case where the functions of the above embodiments are realized when the OS (operating system) and the like, operating on a computer, fully or partially carries out the actual processing based on the instructions of the program codes.

In addition, the present invention provides a case where program codes read from a storage medium are recorded in the memory of a function expansion card inserted in a computer, or the memory of a function expansion unit connected to a computer, the CPU of the function expansion card or function expansion unit the actual processing based on the instructions of the program codes and, thus, implements the functions of the above embodiments.

As described above, according to the embodiments, when the printing process on the printer is interrupted due to disconnecting the cable connecting the DSC and the PFP printer, after which the printing process can be resumed by reconnecting the cable, the printing process can be reliably resumed for printing.

Image data retransmitted from the DSC to the printer is changed when printing is resumed in accordance with either the print process based on the DPOF file or the print process of the image data sequentially transmitted from the DSC to the printer. In any case, printing can be reliably resumed.

When the DSC, according to the embodiments, issues a command to the printer, for example, StartJob or AbortJob, the DSC assumes that a predetermined state has been set even in the absence of any response from the printer, and may decide on the next operation. The DSC additionally issues a command to confirm the status of the printer and can identify the current status (status) of the printer.

When the SFP printer returns a specific status as a response to a DSC, the DSC transfers to the corresponding process. For example, for "NotExecuted" or "NotSupported", the DSC issues a command requesting the printer status for the previous command and decides on the next command to be issued based on the response. For the last command, the previously issued command is not supported by the printer, and thus, the DSC performs a process, for example, changing the PI displayed on the display unit so as not to issue the same command sequentially. This may prevent you from sending a useless command to the printer again.

In addition, when the PFP printer and the DSP almost simultaneously issue commands, both or at least one of the devices prohibits the issuance of the command for a predetermined period of time. This may reduce the ability to issue commands from two devices again almost simultaneously.

According to embodiments, the amount of image data obtained once from the DSC can be adjusted in accordance with the memory capacity or the processing power of the printer. Image data can be downloaded, processed and printed.

The present invention is not limited to the foregoing embodiments, and various changes and modifications can be proposed within the spirit and scope of the present invention. Therefore, the scope of the present invention is defined by the following claims.

Claims (16)

1. An image supply device used in a recording system in which an image supply device and a recording device communicate with each other via a data transmission interface and image data is transmitted from an image supply device to a recording device and recorded, characterized in that it comprises command issuing means for issuing a predetermined command to the recording device, receiving means for receiving a signal from the recording device after the command issuing command has issued a predetermined command, determination means for determining whether the reception means has received a command other than a response corresponding to a predetermined command before receiving the response, and control means for controlling timing of issuing the next command to the recording device when the determining means determines that the receiving means has received a command other than the response corresponding to the predetermined command before receiving the response. 2. The device according to claim 1, which also contains a means of cancellation to cancel the command received from the recording device in the case when the determination means determined that the command, other than the response corresponding to a predetermined command, was received before receiving the response. 3. A recording device used in a recording system in which an image supply device and a recording device communicate with each other via a data transmission interface and image data is transmitted from an image supply device to a recording device and recorded, characterized in that it comprises command issuing means for issuing a predetermined command to the image pickup device, reception means for receiving a signal from the image pickup device after the command issuing command has issued a predetermined command, determination means for determining whether the reception means has received a command other than a response corresponding to a predetermined command before receiving the response, and control means for controlling timing of issuing the next command to the image supply device in the case where the determining means determines that the receiving means has received a command other than the response corresponding to the predetermined command before receiving the response. 4. The device according to claim 3, which also contains a means of cancellation to cancel the command received from the image supply device in the case when the determination means determined that a command other than the response corresponding to a predetermined command was received before receiving the response. 5. A control method for a recording system in which an image supply device and a recording device communicate with each other via a data transmission interface and image data is transmitted from the image supply device to the recording device and recorded, characterized in that it comprises the step of issuing a command in which a specific command is issued between the image pickup device and the recording device, a determination step, which determines whether or not the command received from the partner to the response corresponding to the predetermined command, the response corresponding to the predetermined command, and a change step, in which the timing of issuing the next command in at least one of the image supply device and the recording device is changed when it is determined in the determination step that the command received from the partner before receiving the response corresponding to the predetermined command is not response corresponding to a predetermined command. 6. The method according to claim 5, which also comprises the step of canceling the command received from the partner, in the case when the determining means determined that the command, other than the response corresponding to the predetermined command, was received before receiving the response. 7. A method of controlling an image supply device used in a recording system in which an image supply device and a recording device communicate with each other via a data transmission interface and image data is transmitted from an image supply device to a recording device and recorded, comprising the step of issuing commands, at which a predetermined command is issued to the recording means, a receiving step, at which a signal is received from the recording means after a predetermined command is issued at the command issuing step, a determining step in which it is determined whether a command other than a response corresponding to a predetermined command was received at the receiving stage before receiving the response, and a control step, in which the timing of issuing the next command to the recorder is controlled when it is determined in the determination step that a command other than the response corresponding to the predetermined command has been received before receiving the response in the receiving step. 8. The control method according to claim 7, in which at the control stage the timing of the next command is delayed for a predetermined period of time. 9. The control method of claim 8, in which a predetermined period of time varies randomly. 10. The control method according to claim 8, in which a predetermined period of time is updated every time when it is determined at the determination stage that the signal is not a response corresponding to a predetermined command. 11. The method according to claim 7, which also includes the step of canceling the command received from the recording device, in the case when the determining means determined that the command, other than the response corresponding to the predetermined command, was received before receiving the response. 12. A method for controlling a recording device used in a recording system in which an image supply device and a recording device communicate with each other via a data transmission interface and image data is transmitted from an image supply device to a recording device and recorded, the method comprises the step of issuing a command, at which a predetermined command is issued to the image pickup device, a receiving step, at which a signal is received from the image pickup device after a predetermined command is issued at the command issuing step, a determining step in which it is determined whether a command other than a response corresponding to a predetermined command was received at the receiving stage before receiving the response, and a control step in which the timing of issuing the next command to the image pickup device is controlled when it is determined in the determination step that a command other than the response corresponding to the predetermined command has been received before receiving the response in the reception step. 13. The control method according to item 12, in which at the control stage the timing of the next command is delayed for a predetermined period of time. 14. The control method according to item 12, in which a predetermined period of time varies randomly. 15. The method according to item 13, in which a predetermined period of time is updated every time when it is determined at the determination stage that the signal is not a response corresponding to a predetermined command. 16. The method of claim 12, further comprising the step of canceling a command received from the image pickup device when the determining means determined that a command other than the response corresponding to the predetermined command was received before receiving the response.

Images