Patent Grant
10895839
Field of the Invention
The present invention relates to an image forming apparatus capable of executing double-sided printing, a control method therefor, and a storage medium.
Description of the Related Art
Recently, printers have achieved high resolutions, with printers having resolutions of 600 dpi (dots/inch) and 1,200 dpi making their debuts. Those printers switch the resolution between 600 dpi and 1,200 dpi by changing the conveying speed of printing paper (sheet). More specifically, when a sheet conveying speed corresponding to 600 dpi is defined as the first constant speed, printing at a 1,200-dpi double resolution is implemented by conveying a sheet at a speed (half speed) that is half the first constant speed. Therefore, in 1,200-dpi printing, the sheet conveying speed is halved, halving the productivity of 600 dpi printing. To implement 1,200-dpi printing at the first constant speed, the rotational speed of a polygon mirror which scans a laser beam is doubled, or the number of laser beams is doubled, raising the hardware cost. To implement high-resolution printing at low cost, switching of the resolution by switching the conveying speed is an indispensable technique. For example, Japanese Patent Laid-Open Nos. 2000-181275 and 2002-23576 have proposed this technique.
As a method of forming images on the obverse and reverse surfaces of many sheets, a circulation paper conveying method is used. In this method, a sheet is sent to a transfer unit configured to transfer an image, and an image is printed on one surface of the sheet. The sheet is then sent to an inversion unit and inverted. The inversed sheet is then sent again to the transfer unit, and an image is transferred on the reverse surface, thereby printing images on the two surfaces of the sheet. To increase productivity by shortening the interval between sheets, double-sided circulation control is performed in double-sided printing. More specifically, instead of feeding and refeeding one sheet, a plurality of sheets are fed at once to successively print images on their first surfaces, and the sheets each bearing the image on the first surface are sent to a double-sided path. Then, images for the first surfaces of newly fed sheets, and images for the second surfaces of the sheets conveyed via the double-sided path are alternately printed.
As an image forming apparatus using the circulation paper conveying method, Japanese Patent No. 03768785 has proposed an image forming apparatus which decides a double-sided circulating sheet count based on the paper size and paper type of a sheet to be fed. Even if there is a sheet to be printed subsequently, control to temporarily interrupt double-sided circulation is performed under a given condition. For example, when the paper size switches from A4 to A3, double-sided circulation is interrupted. This is because the circulating sheet count switches depending on the paper size and paper type. Also, when the paper type switches (from plain paper to thick paper), double-sided circulation is interrupted because the conveying speed switches.
Conventional sheet double-sided circulation control in Japanese Patent No. 03768785 is executed for each sheet. This is because the double-sided circulating sheet count is obtained based on sheet information such as “paper size” and “paper type”. The sheet conveying speed is also switched based on “paper type”. This is because the conveying speed is decreased for a sheet having a large grammage such as thick paper, so as to increase the heat capacity and implement stable fixing.
However, in Japanese Patent No. 03768785, whether to interrupt double-sided circulation is determined not based on the resolution but based on sheet information such as “paper size” and “paper type”. For this reason, even if the conveying speed changes between printing sheets when printing images having different resolutions on a plurality of printing sheets, double-sided circulation cannot be properly interrupted, generating a jam.
The present invention enables realization of a technique capable of preventing generation of a sheet jam and continuously executing double-sided printing even if a plurality of images having different resolutions are printed on respective printing sheets when executing double-sided printing on a plurality of printing sheets.
One aspect of the present invention provides an image forming apparatus arranged to perform image formation on the surfaces of a double-sided sheet by image forming on a first surface of the fed sheet, re-feeding the sheet, and image forming on a second surface of the sheet, the image forming apparatus comprising: an image forming unit configured to form images on the sheet; a circulating path configured to re-feed the sheet to the image forming unit following forming of an image on the first surface of the sheet and after inverting the sheet to enable an image to be formed on the second surface of the sheet; a deciding unit configured to decide a conveying speed of the sheet in accordance with a resolution of the images to be formed by the image forming unit; a comparing unit configured to compare the conveying speed of a subsequent sheet to be fed to the image forming unit, in order that an image can be formed by the image forming unit on a first surface of the subsequent sheet, and the conveying speed of a previous sheet which was fed immediately before the subsequent sheet, in order that an image can be formed by the image forming unit on the second surface of the previous sheet and a feeding control unit configured to control a feeding timing of the subsequent sheet based on the output of the comparing unit.
Another aspect of the present invention provides a method of an image forming apparatus arranged to perform image formation on the surfaces of a double-sided sheet by image forming on a first surface of the fed sheet, re-feeding the sheet, and image forming on a second surface of the sheet, the method comprising: feeding the sheet to an image forming unit arranged to form images on the sheet; re-feeding the sheet to the image forming unit following forming of an image on the first surface of the sheet and after inverting the sheet to enable an image to be formed on the second surface of the sheet; deciding a conveying speed of the sheet in accordance with a resolution of the images to be formed by the image forming unit; comparing the conveying speed of a subsequent sheet to be fed to the image forming unit, in order that an image can be formed by the image forming unit on a first surface of the subsequent sheet, and the conveying speed of a previous sheet which was fed immediately before the subsequent sheet, in order that an image can be formed by the image forming unit on the second surface of the previous sheet; and controlling a feeding timing of the subsequent sheet based on the output of the comparing step.
Still another aspect of the present invention provides a computer-readable storage medium storing a computer program for causing a computer to execute each step in a method for controlling an image processing apparatus.
Further features of the present invention will be apparent from the following description of embodiments with reference to the attached drawings.
Embodiments of the present invention will now be described in detail with reference to the drawings. It should be noted that the relative arrangement of the components, the numerical expressions and numerical values set forth in these embodiments do not limit the scope of the present invention unless it is specifically stated otherwise. Each of the embodiments of the present invention described below can be implemented solely or as a combination of a plurality of the embodiments or features thereof where necessary or where the combination of elements or features from individual embodiments in a single embodiment is beneficial.
A reader unit (image input apparatus) 200 optically reads a document image and converts it into image data. The reader unit 200 includes a scanner unit 210 having a function of reading a document, and a document feed unit (DF unit) 250 having a function of conveying a document to be read.
A printer unit (image output apparatus) 300 conveys a sheet, prints image data as a visible image on it, and discharges the sheet from the apparatus. The printer unit 300 includes a paper feed unit 310 including a plurality of types of sheet cassettes, a marking unit 320 having a function of transferring and fixing image data onto a sheet, and a discharge unit 330 having a function of outputting a printed sheet from the apparatus.
A control unit 110 includes a CPU 120, image memory 130, nonvolatile memory 140, RAM 150, ROM 160, and operation unit 170. The control unit 110 is electrically connected to the reader unit 200 and printer unit 300. The CPU 120 in the control unit 110 provides a copy function by controlling the reader unit 200 to load image data of a document into the image memory 130, and controlling the printer unit 300 to output image data in the image memory 130 onto a sheet. The nonvolatile memory 140 stores various adjustment values. The RAM 150 is used as the work area of the CPU 120, and the ROM 160 stores a control program for the CPU 120. The operation unit 170 includes an LCD touch panel 360 (
First, the reader unit 200 will be explained.
In the reader unit 200, the document feed unit (DF unit) 250 feeds document sheets sequentially one by one from the top onto a platen glass 211, and after the end of a document reading operation, discharges the document sheet on the platen glass 211 to a discharge tray 219. When a document sheet is conveyed onto the platen glass 211, a lamp 212 is turned on, an optical unit 213 starts moving, and the document sheet is exposed and scanned. Light reflected by the document sheet is guided to a CCD image sensor (to be referred to as CCD hereinafter) 218 by mirrors 214, 215, and 216 and a lens 217. The CCD 218 reads the image of the scanned document. Image data output from the CCD 218 undergoes predetermined processing, and is transferred to the control unit 110.
Next, the printer unit 300 will be explained.
A laser driver 321 drives a laser emitting unit 322, and causes the laser emitting unit 322 to emit a laser beam corresponding to image data output from the control unit 110. The laser beam irradiates a photosensitive drum 323 via a polygon mirror, forming a latent image corresponding to the laser beam on the surface of the photosensitive drum 323. A developing unit 324 applies a developer to the latent image on the photosensitive drum 323.
In the printer unit 300, the paper feed unit includes paper feed cassettes 311, 312, 313, and 314 each having a drawer shape. The paper feed unit 310 further includes a manual paper feed tray 315. The printer unit 300 feeds a sheet from one of the paper feed cassettes 311, 312, 313, and 314 and the manual paper feed tray 315, and conveys it to a transfer unit (printing unit) 325 via a conveying path 331. The transfer unit 325 transfers, onto the sheet, the developer applied to the photosensitive drum 323. A conveyor belt 326 conveys the developer-transferred sheet to a fixing unit 327, and the developer is fixed to the sheet by the heat and pressure of the fixing unit 327. The sheet having passed through the fixing unit 327 passes through conveying paths 335 and 334 and is discharged. When inverting the printed surface and discharging a sheet, the sheet is guided to conveying paths 336 and 338, then conveyed in the reverse direction from the conveying path 338, and passes through a conveying path 337 and the conveying path 334. When double-sided printing is set, a sheet having passed through the fixing unit 327 is guided from the conveying path 336 to a conveying path 333 by a flapper 329. Then, the sheet is conveyed in the reverse direction, and guided to the conveying path 338 and a paper refeed conveying path 332 (circulating path) by the flapper 329. The printed sheet guided to the paper refeed conveying path 332 passes through a conveying path 331 at the above-described timing, and fed again to the transfer unit 325. Note that a sheet discharged from the conveying path 334 is conveyed to a discharge bin 350 regardless of single- or double-sided printing.
Next, the operation unit 170 will be described with reference to
An LCD touch panel 360 is used when the user makes main mode settings and displays a status. A ten-key pad 361 is used when the user enters a numerical value of 0 to 9. An ID key 362 is used to enter a department number and password mode when the multi-function peripheral is managed. A reset key 363 is used to reset a set mode. A guide key 364 is used to display an explanation screen for each mode. A user mode key 365 is used to enter a user mode screen. An interrupt key 366 is used to perform interrupt copying. A start key 367 is used to start a copy operation. A stop key 368 is used to stop a running copy job. When the user presses a soft power SW 369, the backlight of the LCD touch panel 360 is turned off, and the multi-function peripheral shifts to a low-power state. When the user presses a power saving key 370, the multi-function peripheral enters the power saving state, and when he presses the power saving key 370 again, returns from the power saving state.
An adjustment key 371 is used to adjust the contrast of the LCD touch panel 360. When the user presses a counter check key 372, a count screen appears on the LCD touch panel 360 and displays a total copy count used until now. An LED 373 represents that a job is being executed and an image is being accumulated in the image memory. An error LED 374 represents that the multi-function peripheral is in an error status such as generation of a jam or opening of the door. An LED 375 is a power LED representing that the main switch of the multi-function peripheral is ON.
A sheet conveying method when forming an image will be explained with reference to
When performing single-sided printing, a sheet S fed from the manual paper feed tray 315 passes through the conveying path 331 and is conveyed to the transfer unit 325, as shown in
When discharging the sheet S with the transferred image facing down, the sheet S on which an image has been transferred by the transfer unit 325 passes through the conveying paths 336 and 338, is then conveyed in the reverse direction from the conveying path 338, passes through the fixing unit 327, and is discharged, as shown in
A sheet conveying method when performing double-sided printing will be explained with reference to
Referring to
As shown in
A sheet conveying method (paper feed control) when performing circulating double-sided printing will be explained with reference to
The circulating sheet count changes mainly depending on the sheet size because the length of the conveying path is determined. For small-size sheets, a large number of sheets can be fed in advance and circulated. To the contrary, for large-size sheets, only a small number of sheets can be fed in advance, decreasing the circulating sheet count.
As shown in
The circulating sheet count changes to three or five in order to efficiently perform double-sided printing at different sheet sizes on the same paper path.
The circulating sheet count is basically decided from the paper (sheet) size. For example, as shown in
The conveying speed is decided from the paper type and resolution. For example, the conveying speed is a constant speed when the paper type is “plain paper” and the resolution is “600 dpi”, and a half speed when the paper type is “thick paper” because of the following reason. A developer is fixed to a sheet by the heat and pressure of the fixing unit 327. However, it is hard to transfer heat to a sheet of the paper type “thick paper”. In this case, the conveying speed is decreased to a half speed so that a larger amount of heat can be transferred to the sheet, implementing stable fixing.
Also, when the resolution is 1,200 dpi, the conveying speed becomes a half speed in order to form a high-resolution latent image on the photosensitive drum 323 with the same number of laser beams at the same rotational speed of the polygon mirror as those for 600 dpi, and transfer, to a sheet by the transfer unit 325, the developer applied to the photosensitive drum 323.
Sheet conveyance control in a conventional image forming apparatus and the image forming apparatus according to the first embodiment will be described with reference to
All paper A to paper E have the paper size “A4” and paper type “plain paper”. The resolutions of images to be printed on these sheets are 600 dpi except for the refeed surface (reverse surface) (fourth document page) of paper B. The resolution of the refeed surface (reverse surface) (fourth document page) of paper B is 1,200 dpi. In
It is determined whether to continue double-sided circulation by feeding the feed surface (fifth document page) of paper C after feeding the feed surface (third document page) of paper B, or interrupt double-sided circulation by refeeding the refeed surface (second document page) of paper A and the refeed surface (fourth document page) of paper B. In sheet conveyance control of the conventional image forming apparatus, the circulating sheet count and conveying speed in double-sided printing are obtained from the paper size and paper type of a sheet, so paper B and paper C are compared with each other. Since both paper B and paper C have the paper size “A4” and paper type “plain paper”, their circulating sheet counts and conveying speeds in double-sided printing are “5” and “constant speed”, and coincide with each other. It is therefore determined that double-sided circulation can continue.
However, if double-sided circulation continues, as shown in
This is applied to
It is determined whether to continue double-sided circulation by feeding the feed surface (fifth document page) of paper C after feeding the feed surface (third document page) of paper B, or interrupt double-sided circulation by refeeding the refeed surface (second document page) of paper A and the refeed surface (fourth document page) of paper B. The control unit 110 makes this determination. In sheet conveyance control according to the first embodiment, the conveying speed is obtained not only based on the paper size and paper type of a sheet but also based on the resolution of the printing surface (conveying speed decision). That is, not only whether to perform double-sided circulation for each paper is determined, but also whether to continue or interrupt double-sided circulation is determined by comparing the conveying speeds of printing surfaces.
More specifically, a feed surface (fifth document page) 1202 of paper C and a feed surface (third document page) 1201 of paper B are compared with each other. Since both paper C and paper B have the paper size “A4” and paper type “plain paper”, their double-sided circulating sheet counts are “5” in the table of
Then, the feed surface (fifth document page) 1202 of paper C and a refeed surface (fourth document page) 1204 of paper B are compared with each other. Since both paper C and paper B have the paper size “A4” and paper type “plain paper”, their double-sided circulating sheet counts are “5” in the table of
This processing starts when the control unit 110 starts sheet conveyance control. In step S101, the control unit 110 determines which of ON and OFF is set at a double-sided circulation interrupt flag in the RAM 150. If the double-sided circulation interrupt flag is ON, the process advances to step S112; if it is OFF, to step S102. In step S102, the control unit 110 checks whether there is paper (sheet) waiting for feed. If there is paper waiting for feed, the process advances to step S103; if there is no paper waiting for feed, to step S112.
In step S103, the control unit 110 determines whether there is paper waiting for refeed. If there is no paper waiting for refeed, the process advances to step S110; if there is paper waiting for refeed, to step S104. In step S110, the control unit 110 checks whether double-sided printing is set for the first paper waiting for feed. If single-sided printing is set, the process advances to step S111; if double-sided printing is set, to step S109. In step S111, the control unit 110 feeds the first paper waiting for feed to the discharge bin 350 serving as a discharge destination, ending the sheet conveyance control. If double-sided printing is set, the control unit 110 feeds the first paper waiting for feed to the paper refeed conveying path 332 serving as a discharge destination in step S109, ending the sheet conveyance control. The processes in steps S109 to S111 are general processes.
If there is paper waiting for refeed, the process advances to step S104, the control unit 110 performs double-sided circulation interrupt determination processing, and then the process advances to step S105. Details of double-sided circulation interrupt determination processing will be described with reference to the flowchart of
In step S105, the control unit 110 determines the result of the double-sided circulation interrupt determination processing in step S104. If the result of the double-sided circulation interrupt determination processing is “FALSE”, that is, the control unit 110 determines not to interrupt double-sided circulation, the process advances to step S106; if “TRUE” (interrupt), to step S107. In step S106, the control unit 110 determines whether the number of sheets waiting for refeed is larger than (double-sided circulating sheet count obtained from the table of
If the double-sided circulation interrupt flag is ON in step S101 or there is no paper waiting for feed in step S102, the process advances to step S112, and the control unit 110 determines whether there is paper waiting for refeed. If the control unit 110 determines that there is paper waiting for refeed, the process advances to step S108. If the control unit 110 determines that there is no paper waiting for refeed, the process advances to step S113, and the control unit 110 sets the double-sided circulation interrupt flag OFF in the RAM 150, ending the sheet conveyance control.
By the above processing, paper feed can be controlled by determining not only whether to perform double-sided circulation for each paper, but also determining whether to continue or interrupt double-sided circulation, by comparing the conveying speeds of printing surfaces, as described with reference to
This processing starts when the control unit 110 starts processing of determining whether to interrupt double-sided circulation. In step S201, the control unit 110 determines which of single-sided printing and double-sided printing is set for paper waiting for feed. If single-sided printing is set, the process advances to step S205, and the control unit 110 decides TRUE (to interrupt double-sided circulation) in double-sided circulation interrupt determination, ending the determination processing.
If the control unit 110 determines in step S201 that double-sided printing is set, the process advances to step S202, and the control unit 110 obtains a double-sided circulating sheet count by looking up the table of
If the control unit 110 determines in step S204 that the double-sided circulating sheet counts coincide with each other, the process advances to step S206, and the control unit 110 obtains a conveying speed by looking up the table of
If the control unit 110 determines in step S208 that the conveying speeds coincide with each other, the process advances to step S209, and the control unit 110 obtains a conveying speed by looking up the table of
In step S211, the control unit 110 obtains a conveying speed by looking up the table of
In the above-described determination processing, it is decided to interrupt double-sided circulation when one of the following three conditions is not satisfied based on the paper size, paper type, and resolution:
(1) whether the process speed of the feed surface of the first paper waiting for feed and that of the refeed surface of the first paper waiting for feed coincide with each other, (2) whether the process speed of the feed surface of the first paper waiting for feed and that of the feed surface of the final paper waiting for refeed coincide with each other, and (3) whether the process speed of the feed surface of the first paper waiting for feed and that of the refeed surface of the final paper waiting for refeed coincide with each other.
A sheet conveyance control method by the image forming apparatus according to the first embodiment will be explained with reference to
First, when feeding paper A, the control unit 110 advances to steps S101, S102, S103, S110, and S109 of
In double-sided circulation interrupt processing, the control unit 110 advances to step S201 of
Again, when feeding paper B, the control unit 110 advances to step S101, S102, S103, S110, and S111 of
When feeding paper C, the control unit 110 advances to step S101, S102, S103, S110, and S109 of
When feeding paper D, the control unit 110 advances to step S101, S102, S103, and S104 of
Again, when feeding paper D, the control unit 110 advances to step S101, S102, S103, S110, and S109 of
Further, both the feed surface (eighth document page) of paper E and the refeed surface (seventh document page) of paper D commonly have “A4”, “plain paper”, and “1200 dpi”, and their conveying speeds are “half speed” in
When feeding paper F, the control unit 110 advances to step S101, S102, S103, and S104 of
Further, the control unit 110 compares the conveying speed of the feed surface (10th document page) of paper F and that of the refeed surface (ninth document page) of paper E. Both the feed surface of paper F and the refeed surface of paper E have “A4”, “plain paper”, and “1200 dpi”, and their conveying speeds are “half speed” in
When feeding paper G, the control unit 110 advances to step S101, S102, S103, and S104 of
Again, when feeding paper G, the control unit 110 advances to step S101, S102, S103, and S104 of
Thereafter, the control unit 110 advances to steps S105 and S106 of
Next, a case in which paper H is fed will be explained. The control unit 110 advances to steps S101, S102, S103, and S104 of
The control unit 110 determines which of paper H waiting for feed is to be fed or paper F waiting for refeed is to be refed. At this time, the double-sided circulation interrupt flag has been ON in step S107 in the previous paper feed determination for paper H. Hence, the control unit 110 advances from step S101 to steps S112 and S108. In step S108, the control unit 110 refeeds paper F serving as the first paper waiting for refeed to the discharge bin 350 serving as a discharge destination, ending the sheet conveyance control.
After that, the control unit 110 determines which of paper H waiting for feed is to be fed or paper G waiting for refeed is to be refed. At this time, the double-sided circulation interrupt flag has been ON in step S107 in the previous paper feed determination for paper H. The control unit 110 therefore advances from step S101 to steps S112 and S108 in
When feeding paper H, the double-sided circulation interrupt flag has been ON in step S107 in the previous paper feed determination for paper H. Thus, the control unit 110 advances from step S101 to step S112. In step S112, paper F and paper G waiting for refeed have already been refed, so there is no paper waiting for refeed. The control unit 110 advances to step S113, and sets the double-sided circulation interrupt flag OFF. The control unit 110 advances to steps S110 and S109, and feeds paper H serving as the first paper waiting for feed to the paper refeed conveying path 332 serving as a discharge destination for double-sided printing, ending the sheet conveyance control.
When feeding paper I, the control unit 110 advances to steps S101, S102, S103, and S104 of
Again, when feeding paper I, the control unit 110 advances to step S101, S102, S103, S110, and S109 of
The above-described feed & refeed order is shown in
In the above-described method according to the first embodiment, when determining whether to continue double-sided circulation, it is determined whether the resolutions of the feed and refeed surfaces of paper (printing medium) to be fed next are different from each other, or whether the resolution of the feed surface of paper to be fed next and that of the feed surface of immediately previously fed paper are different from each other. Further, it is determined whether the resolution of the feed surface of paper to be fed next and that of the refeed surface of immediately previously fed paper are different from each other. If the resolutions differ from each other in one of these conditions, it is determined to interrupt double-sided circulation. Accordingly, double-sided printing can be executed efficiently.
The second embodiment of the present invention will be described with reference to
All paper A to paper F have the paper size “A4” and paper type “plain paper”. The resolution is basically 600 dpi, but 1,200 dpi for only the feed surface (fourth document page) and refeed surface (blank surface) of paper C. Note that a 1200-dpi printing surface is hatched.
The 1200-dpi fourth document page is laid out on the reverse surface of paper B in
This processing starts when the control unit 110 starts double-sided imposition processing. In step S301, the control unit 110 confirms whether a document has been added. If a document to be printed has been added, the process advances to step S302; if NO, returns to step S301 to wait until the next document is added. In step S302, the control unit 110 determines whether there is paper waiting for reverse surface imposition. If the control unit 110 determines that there is paper waiting for reverse surface imposition, the process advances to step S303. If NO in step S302, the process advances to step S307, and the control unit 110 newly generates paper waiting for reverse surface imposition, and associates the document with the obverse surface of the paper, ending the double-sided imposition processing.
In step S303, the control unit 110 determines whether the resolution of the obverse surface of paper waiting for reverse surface imposition and the resolution of the document coincide with each other. If the control unit 110 determines that the resolutions coincide with each other, the process advances to step S304, the control unit 110 associates the document with the reverse surface of paper waiting for reverse surface imposition, and the process advances to step S305. In step S305, the control unit 110 feeds the paper waiting for reverse surface imposition, ending the double-sided imposition processing.
If the control unit 110 determines in step S303 that the resolutions do not coincide with each other, the process advances to step S308, and the control unit 110 associates blank paper with the reverse surface of paper waiting for reverse surface imposition. The control unit 110 inserts the blank paper and performs imposition so that the resolutions of the obverse and reverse surfaces coincide with each other. Then, the process advances to step S309. In step S309, the control unit 110 feeds the paper which has the reverse surface associated with the blank paper in step S308 and waits for reverse surface imposition. After that, the process advances to step S307. In step S307, the control unit 110 newly generates paper waiting for reverse surface imposition, and associates the document with the obverse surface, ending the double-sided imposition processing.
As described above, according to the second embodiment, the resolutions of the feed and refeed surfaces of paper (printing medium) to be fed next always coincide with each other. Conveyance control suitable for even double-sided circulation control for each paper can be executed.
Aspects of the present invention can also be realized by a computer of a system or apparatus (or devices such as a CPU or MPU) that reads out and executes a program recorded on a memory device to perform the functions of the above-described embodiment(s), and by a method, the steps of which are performed by a computer of a system or apparatus by, for example, reading out and executing a program recorded on a memory device to perform the functions of the above-described embodiment(s). For this purpose, the program is provided to the computer for example via a network or from a recording medium of various types serving as the memory device (for example, computer-readable medium).
While the present invention has been described with reference to exemplary embodiments, it is to be understood that the invention is not limited to the disclosed exemplary embodiments. The scope of the following claims is to be accorded the broadest interpretation so as to encompass all such modifications and equivalent structures and functions.
This application claims the benefit of Japanese Patent Application No. 2011-193275 filed on Sep. 5, 2011, which is hereby incorporated by reference herein in its entirety.
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| Number | Date | Country | |
|---|---|---|---|
| Parent | 13596650 | Aug 2012 | US |
| Child | 15171567 | US |
