JP2010260301A - Image forming apparatus - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To automatically select a paper feeder, based on the size value of image data and the size value of a printing paper, by considering unit conversion. <P>SOLUTION: An image forming apparatus provided with one or a plurality of paper feeders includes: a receiving means receiving the image data whose size value is specified; a paper feeder setting accepting means accepting the setting of the size value of the printing paper stored in the paper feeder; and a paper feeder deciding means deciding the paper feeder storing the printing paper having the same size value as the size value of the received image data as the selected paper feeder. The paper feeder deciding means regards the size value of the image data and the size value of the printing paper as the same, when a difference between the size value of the image data and the size value of the printing paper is within a predetermined allowable range value. <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

  The present invention relates to an image forming apparatus, and more particularly to an image forming apparatus that automatically selects a sheet feeding device based on the size of image data.

  As described in Patent Document 1, in an image forming apparatus having a plurality of paper feeding devices, a function of automatically selecting a paper feeding device based on the size of image data sent from a host computer is widely used. It has been.

  In such an image forming apparatus, a paper feeding apparatus storing a printing paper having a size that matches the size of the image data is automatically selected. However, a printing paper having a size that matches the size of the image data is stored. If there is no paper feeding device, for example, it is processed as a paper feeding device error. Alternatively, as described in Japanese Patent Application Laid-Open No. H10-228707, there is a device that selects a paper feeding device that stores printing paper having a size closest to the size of image data.

  In general, in an image forming apparatus, image formation can be performed on printing paper of an arbitrary size in addition to printing paper of a standard size such as A4 and B5. In order to enable automatic selection of the paper feeding device even when image formation is performed on printing paper of an arbitrary size, the image data size is set numerically in the host computer, and the image forming device also supplies the paper. The printing paper size stored in the paper device is set numerically. The size is usually set by the width and length, and the size set by these numerical values is called a custom size.

  By setting the custom size in this way, the image forming apparatus can automatically select a paper feeding device that stores printing paper having a size value that matches the size value of the image data sent from the host computer. It becomes like this.

JP 2004-338189 A

  However, the unit system for which a custom size is set may differ from the unit system handled in the host computer or the image system generation apparatus. For example, when the image size and paper size are set in inches in a printing system in which internal processing in the host computer and the image system generating device is performed in millimeter units, or in the printing system including a plurality of devices, internal processing is performed in different unit systems. This includes the case where a device that performs the above is included.

  In such a case, unit conversion is performed in a host computer, an image forming apparatus, or the like. In general, rounding is performed in unit conversion, which may cause an error. Also, the resolution after the decimal point may differ depending on the device. For this reason, even if the same size value is set in the host computer and the image forming apparatus, the unit conversion may result in handling with different size values.

  If the unit conversion results in different size values, the image forming apparatus determines that there is no sheet feeding apparatus that stores printing paper of a size that matches the image data, resulting in a sheet feeding apparatus error. Further, in order to prevent a paper feeding device error, if a paper feeding device storing a printing paper of the closest size is selected as described in Patent Document 1, a custom size printing paper is loaded in the image forming apparatus. If it is not prepared, an image is formed on an unintended size printing paper.

  SUMMARY An advantage of some aspects of the invention is that it provides an image forming apparatus that automatically selects a paper feeding device based on a size value of image data and a size value of printing paper in consideration of unit conversion.

  In order to solve the above-described problem, according to the present invention, an image forming apparatus including one or a plurality of paper feeding devices, receiving means for receiving image data in which a size value is designated, and the paper feeding device Paper feeding device that accepts the setting of the size value of the stored printing paper and the paper feeding device that stores the printing paper having the same size value as the size value of the received image data. A paper feeding device determining means for determining the device, and the paper feeding device determining means is configured to detect the image if the difference between the size value of the image data and the size value of the printing paper is within a predetermined allowable range value. There is provided an image forming apparatus that assumes that the size value of data and the size value of the printing paper are the same.

  When unit conversion is performed, an error may occur even with the same size value depending on the content of the conversion process. In the present invention, since a predetermined error is allowed and a match between the size of the image data and the size of the printing paper is determined, a printing paper having a matching size is stored even though a suitable printing paper is stored. It can be prevented that it is determined that there is no sheet feeding device. Further, it is possible to prevent an image from being formed on a printing paper of an unintended size.

  For this reason, it is preferable that the predetermined allowable range value is determined based on a maximum error that may occur due to a rounding error in unit conversion with respect to the size value.

  More specifically, when the unit conversion for the size value is unit conversion from millimeter to inch or unit conversion from inch to millimeter, the predetermined allowable range value may be set to 1 mm, for example. it can. Of course, the predetermined allowable range value may be changeable by the user.

  Here, if the size of the image data and the size of the printing paper can be regarded as the same by rotating the image data, the paper feeding device determination means stores the printing paper. Can be determined as a paper feeding device that feeds paper.

  The image data further specifies a paper type, and the paper feeding device setting accepting unit further accepts a paper type setting of a printing paper stored in the paper feeding device, and determines the paper feeding device. In the case where the size value of the image data and the size value of the printing paper can be regarded as the same, the means is that the paper type of the printing paper is different from the paper type specified in the image data In this case, the paper feeding device storing the printing paper may not be determined as a paper feeding device for feeding paper.

  According to the present invention, an image forming apparatus that automatically selects a paper feeding device based on a size value of image data and a size value of printing paper in consideration of unit conversion is provided.

1 is a block diagram illustrating a configuration of a printing system including a printer according to an embodiment. FIG. 10 is a diagram illustrating an example of a screen in which a sheet feeding device setting receiving unit receives settings related to a sheet feeding device from a user. FIG. 6 is a diagram illustrating an example of a screen for setting information on printing paper stored in a paper feeding device. It is a figure which shows an example of an allowable error range setting screen. 6 is a diagram illustrating an example of a print setting screen. FIG. It is a figure which shows an example of a custom size input screen. It is a figure which shows an example of the image rotation menu which receives the setting regarding image rotation. It is a figure which shows the 1st example which a unit conversion error produces. It is a figure which shows the 2nd example which a unit conversion error produces. It is a figure which shows the 3rd example which a unit conversion error produces. 6 is a flowchart illustrating processing of a paper feeding device determination unit.

  Embodiments of the present invention will be described with reference to the drawings. FIG. 1 is a block diagram illustrating a configuration of a printing system including a printer according to the present embodiment. As shown in the figure, the printing system includes a printer 20 that functions as an image forming apparatus, and a PC 10 that functions as a host computer that outputs print data to the printer 20. The connection form between the PC 10 and the printer 20 may be a LAN connection via the computer network 40, for example. However, it may be a stand-alone connection or a WAN connection.

  In this embodiment, it is assumed that the printer 20 does not have a RIP (Raster Image Processor) function for rasterizing a page description language such as PostScript. For this reason, the printing system includes an RIP device 30 that rasterizes a page description language. The RIP device 30 is connected between the computer network 40 and the printer 20.

  The PC 10 outputs the print data directly to the printer 20 when printing using print data that can be interpreted by the printer 20, and prints using print data in a page description language that cannot be interpreted by the printer 20. Print data is output to the printer 20 via the RIP device 30. In this case, the RIP device 30 rasterizes the print data in the page description language sent from the PC 10 and outputs it to the printer 20. The device that mediates between the PC 10 and the printer 20 is not limited to the RIP device 30, and a device such as a controller that performs other processing can be used.

  A printer driver program developed for the printer 20 is installed in the PC 10, and the printer driver unit 110 is configured by the CPU of the PC 10 executing this program.

  As shown in the figure, the printer driver unit 110 includes a print setting reception unit 111, a print data generation unit 112, and a print data output unit 113.

  The print setting reception unit 111 receives various print settings related to print processing executed by the printer 20 from the user. The print settings received by the print setting receiving unit 111 include document size, output paper size, paper feed device selection, image rotation, and the like. Here, the document size is an image size when a document to be printed is created by the PC 10, and the output paper size is an image size when output to the printer 20. Usually, it is the same size as the document size.

  The user can set the document size and the output paper size by a standard size such as A4 or B5, or can set the custom size by specifying an arbitrary width and length. In the present embodiment, the custom size is designated by width and length in millimeters or inches, but may be designated by points or the like.

  The print data generation unit 112 performs processing for generating print data for printing the document to be printed by the printer 20 based on the print settings. The print data includes image data indicating the content of the image and control data for controlling the printer 20 based on print settings such as designation of a paper feeding device. When generating print data, unit conversion of the output paper size is performed as necessary. The unit conversion is, for example, conversion from inch units to millimeter units. In this case, a rounding error may occur.

  The print data output unit 113 performs processing for outputting the generated print data to the printer 20. As described above, when print data that can be interpreted by the printer 20 is output, it is directly output to the printer 20. When print data in a page description language that cannot be interpreted by the printer 20 is output, the printer is connected via the RIP device 30. 20 is output.

  The printer 20 includes a print data receiving unit 210, a print control unit 220, a printing mechanism unit 230, a paper feeding unit 240, and an operation receiving unit 250. The paper feeding unit 240 has one or a plurality of paper feeding devices. In the present embodiment, it is assumed that four paper feeding devices, that is, a first paper feeding device 241, a second paper feeding device 242, a third paper feeding device 243, and a fourth paper feeding device 244 are provided. Each paper feeding device can store printing papers of different sizes. In this case, custom-size printing paper can be stored in addition to standard-size printing paper such as A4 and B5.

  The print data receiving unit 210 receives print data from the PC 10 or the RIP device 30. The print control unit 220 controls print processing based on the received print data. The print control unit 220 can rotate and print the image data to match the width and length of the printing paper.

  The print control unit 220 includes a paper feeding device determination unit 221 and determines a paper feeding device that feeds paper during printing. When the user does not designate a specific paper feeding device, the paper feeding device determination unit 221 compares the image size of the print data with the size of the printing paper stored in the paper feeding device, and determines the size. The paper feeding device in which the matching printing paper is stored can be determined as a paper feeding device that feeds paper. In this embodiment, at this time, the occurrence of an error due to unit conversion is taken into consideration, and a predetermined error is allowed to perform the size matching determination.

  The printing mechanism unit 230 includes a printing mechanism such as an inkjet head and a paper transport mechanism, and performs image forming processing on the printing paper under the control of the printing control unit 220.

  The operation receiving unit 250 is configured using an operation panel device or the like, displays a menu or the like, and receives various operations, instructions, and the like from the user. In addition, the operation reception unit 250 includes a paper supply device setting reception unit 251 that receives settings related to the paper supply devices 241 to 244 of the paper supply unit 240 from the user.

  FIG. 2 is a diagram illustrating an example of a screen on which the sheet feeding device setting receiving unit 251 receives settings related to the sheet feeding device from the user. The screen 400 includes an area 401 indicating information related to the first paper feeding device, an area 402 indicating information related to the second paper feeding device, an area 403 indicating information related to the third paper feeding device, and information related to the fourth paper feeding device. An area 404 to be shown is included. In each area, the size, paper type, and paper feed setting of the print paper stored in each paper feeder are displayed. Here, the paper feed setting represents the properties of the paper such as the paper thickness. Each area is further provided with a button for accepting designation as to whether or not each sheet feeding device is subject to auto selection.

  The user can designate a paper feeding device to be used for printing by selecting one of the areas. The screen 400 also includes an “auto” button 405. When the “auto” button 405 is designated, the selection of the paper feeding device is left to the paper feeding device determination unit 221 of the printer 20. It is done. In this case, the paper feeding device determination unit 221 selects the paper feeding device to be used for printing based on the size of the printing paper stored in each paper feeding device and the image size of the print data. "Is determined from among the sheet feeding devices that are.

  Further, the user can set the information of the printing paper stored in the paper feeding device by designating the “detail setting” button 406 in a state where any paper feeding device is designated.

  FIG. 3 shows an example of a screen for setting information on printing paper stored in the paper feeding device. In this figure, a list of standard sizes is displayed, and the user can select an item that matches the size of the printing paper stored in the paper feeder. This screen also includes a “standard size detection” button 421. If a standard size printing paper is stored, the “standard size detection” button 421 is selected to automatically change the size of the printing paper. Can be set.

  If the printing paper stored in the paper feeder is not a standard size, the user sets the width and length of the stored printing paper using a custom size input screen (not shown). The width and length of the printing paper can be set in units of millimeters or inches, for example.

  Further, the paper feeding device setting reception unit 251 is a paper feeding device used for printing by the paper feeding device determination unit 221 based on the size of the printing paper stored in each paper feeding device and the image size of the print data. When an automatic selection is made, it is possible to accept setting of an allowable error range that is regarded as the same size. For example, when the allowable error range is set to P millimeters, if the difference between the image size of the print data and the size of the printing paper is within P millimeters, it is determined that they are the same size. The allowable error range is not limited to millimeters, but may be specified by inches, points, or the like.

  In this embodiment, the initial value of the allowable error range is 1 mm. The allowable error range is desirably set to a value that is equal to or greater than the maximum error that can occur during unit conversion described later. The allowable error range may not be specified by the user as a fixed value.

  Next, characteristic print settings of the present embodiment received by the print setting receiving unit 111 of the PC 10 will be described.

  FIG. 5 is a diagram illustrating an example of a print setting screen. As shown in the figure, the screen 500 includes a document size designation menu 501, an output paper size designation menu 502, and a paper feed device selection menu 503.

  As described above, the document size designation menu 501 is a menu for designating an image size when a document to be printed is created by the PC 10. An output paper size designation menu 502 is a menu for designating an image size for output to the printer 20.

  In addition to the standard paper size, an original size specification menu 501 and an output paper size specification menu 502 can specify a custom size of an arbitrary size. FIG. 6 is a diagram illustrating an example of a screen for inputting a custom size. As shown in this figure, the custom size can specify the width and length in millimeters. Of course, it may be specified in units of inches.

  A paper feed device selection menu 503 is a menu for selecting a paper feed device used for printing. With this menu, the user can select a specific paper feeding device among a plurality of paper feeding devices provided in the printer 20. Note that the user can also select “auto”, which entrusts the printer 20 to select the paper feeding device.

  In addition, the print setting receiving unit 111 can receive settings related to image rotation. FIG. 7 is a diagram illustrating an example of an image rotation menu that accepts settings relating to image rotation. As shown in the figure, the image rotation menu 530 accepts selection of “No”, “90 °”, “180 °”, “270 °”, and “Auto”.

  When “No” is selected, the printer 20 does not rotate the image. When any one of “90 °”, “180 °”, and “270 °” is selected, image rotation at a specified angle is performed in the printer 20. When “Auto” is selected, the printer 20 performs optimum image rotation as necessary. Specifically, by rotating the image, the image is rotated at an optimum angle when the size of the printing paper stored in the sheet feeding device and the image size of the print data are the same size.

  As described above, in this embodiment, when automatically selecting a printing apparatus to be used for printing, it is assumed that the size of the printing paper stored in the paper feeding apparatus and the image size of the print data are the same size. A tolerance is provided. This allowable error mainly considers an error that occurs when unit conversion from inch to millimeter or the like is performed when a custom paper size is specified and stored.

  Hereinafter, an error that occurs when performing unit conversion will be described using a specific example. FIG. 8 shows an example of an error that occurs when the image size of the print data is sent from the PC 10 to the printer 20 in units of millimeters. Here, as shown in FIG. 8A, in the PC 10, it is assumed that the resolution of inches is 0.1 inch units and the resolution of millimeters is 1 mm units. The unit conversion from inch to millimeter is performed by millimeter = inch × 25.4. Furthermore, the conversion value is rounded off to the nearest whole number. It is assumed that a custom size is set as an original size in units of inches.

  On the other hand, in the printer 20, it is assumed that the inch resolution is 0.1 inch unit and the millimeter resolution is 1 mm unit. The unit conversion from inch to millimeter is performed by millimeter = inch × 25.4. Furthermore, the conversion value is rounded up. Assume that a custom size is set in inches as the paper size. That is, this example is a case where the PC 10 and the printer 20 have different conversion value rounding rules.

  FIG. 8B is a chart showing unit conversion results and errors that occur. For example, assume that both the PC 10 and the printer 20 input 1.0 inch as the custom size. Since the data unit system of both the PC 10 and the printer 20 is millimeter, conversion from inch to millimeter is performed. In this case, it is converted to 25.40 mm.

  However, rounding is performed because both the PC 10 and the printer 20 have a millimeter resolution of 1 millimeter. Since the rounding rule of the PC 10 is rounded off and the rounding rule of the printer 20 is rounded up, the PC 10 handles it as 25 mm and the printer 20 handles it as 26 mm. Therefore, when print data is sent from the PC 10, an error of 1 mm occurs even though a custom size having the same value is set.

  On the other hand, if 1.1 inches is input as the custom size, no error occurs. Thereafter, up to 3.0 inches is shown in the chart, but an error of 1 mm occurs depending on the input size. Therefore, it is desirable to set 1 mm or more as the allowable error range.

  FIG. 9 is also an example of an error that occurs when the image size of print data is sent from the PC 10 to the printer 20 in millimeters. Here, as shown in FIG. 9A, in the PC 10, it is assumed that the inch resolution is 0.1 inch unit and the millimeter resolution is 1 mm unit. The unit conversion from inch to millimeter is performed by millimeter = inch × 25.4. Furthermore, the conversion value is rounded off to the nearest whole number. It is assumed that a custom size is set as an original size in units of inches.

  On the other hand, in the printer 20, it is assumed that the inch resolution is 0.1 inch unit and the millimeter resolution is 0.1 mm unit. The unit conversion from inch to millimeter is performed by millimeter = inch × 25.4. Furthermore, the conversion value is rounded off to the nearest whole number. Assume that a custom size is set in inches as the paper size. That is, this example is a case where the millimeter resolution is different between the PC 10 and the printer 20.

  FIG. 9B is a chart showing unit conversion results and errors that occur. For example, assume that both the PC 10 and the printer 20 input 1.0 inch as the custom size. Since the data unit system of both the PC 10 and the printer 20 is millimeter, conversion from inch to millimeter is performed. In this case, it is converted to 25.40 mm.

  However, since the millimeter resolution of the PC 10 is 1 millimeter, it is treated as 25 millimeters. On the other hand, since the millimeter resolution of the printer 20 is 0.1 mm, it is handled as 25.4 mm. Therefore, when print data is sent from the PC 10, an error of 0.4 mm occurs even though the same custom size is set.

  On the other hand, when 1.3 inches is input as the custom size, no error occurs. In this chart, 1.0 inch to 3.0 inch is shown, but an error of a maximum of 0.5 mm occurs depending on the input size. Therefore, it is desirable to set the allowable error range to 0.5 mm or more.

  FIG. 10 shows an example of errors that occur when print data is sent from the PC 10 to the printer 20 via the RIP devices 30 of different unit systems. Here, it is assumed that the image size of the print data is sent from the PC 10 to the RIP device 30 in inches, and the image size is sent from the RIP device 30 to the printer 20 in millimeters.

  As shown in FIG. 10A, in the PC 10, it is assumed that the inch resolution is 0.1 inch unit and the millimeter resolution is 1 mm unit. The unit conversion from millimeter to inch is performed by inch = millimeter / 25.4. Furthermore, the conversion value is rounded off to the nearest whole number. Assume that a custom size is set in millimeters as the document size.

  In the RIP device 30, processing is performed in an inch unit system, the resolution of inches is 0.1 inch units, and the resolution of millimeters is 1 mm units. The unit conversion from inch to millimeter is performed by millimeter = inch × 25.4. Furthermore, the conversion value is rounded off to the nearest whole number.

  In the printer 20, it is assumed that the resolution of millimeters is 1 millimeter unit. Assume that a custom size is set in millimeters as the paper size. That is, the PC 10 performs unit conversion from millimeters to inches, and the RIP device 30 performs unit conversion from inches to millimeters. On the other hand, the printer 20 handles only millimeters.

  FIG. 10B is a chart showing unit conversion results and errors that occur. For example, assume that 26 mm is input as the custom size in both the PC 10 and the printer 20. In the PC 10, unit conversion from millimeters to inches is performed. In this case, it is converted to 1.023622047 inches. Since the resolution of the inch in the PC 10 is 0.1 inch, the inch is rounded to 1.0 inch and output to the RIP device 30.

  The RIP device 30 performs unit conversion from inches to millimeters. In this case, it is converted to 25.40 mm. Since the resolution of millimeters in the RIP device 30 is 1 millimeter, it is rounded to 25 millimeters and output to the printer 20.

  Therefore, although both the PC 10 and the printer 20 input 26 mm as a custom size, the printer 20 inputs 25 mm, so that an error of 1 mm occurs.

  On the other hand, when 25 mm is input as the custom size, no error occurs. Although this chart shows from 25 mm to 45 mm, an error of 1 mm at maximum will occur depending on the input size. Therefore, it is desirable to set 1 mm or more as the allowable error range.

  As described above, even though the same custom size is specified by the PC 10 and the printer 20, an error may occur between the size of the image data and the paper size based on the unit conversion.

  Therefore, in the present embodiment, when automatically selecting a printing apparatus to be used for printing, an allowable error is considered that the size of the printing paper stored in the paper feeding apparatus and the image size of the print data are the same size. Provided. In the above example, since the maximum error is 1 mm, it is generally considered sufficient to set the allowable error to 1 mm.

  FIG. 11 is a flowchart for describing a paper feed device determination process of the paper feed device determination unit 221 of the printer 20 when print data is received.

  When print data is received, it is checked whether or not “auto” is set as the paper feed device selection with reference to the print settings included in the print data (S101). As a result, when a specific paper feeding device is set instead of “Auto” (S101: No), the designated paper feeding device is determined as the paper feeding device used for printing (S102).

  When “Auto” is set as the paper feed device selection (S101: Yes), the value of the set paper size allowable error range is acquired (S103). Then, it is determined whether or not there is a paper feeding device that stores printing paper whose size is different from the size of the image data included in the printing data within an allowable error range (S104). In the size comparison, it is determined whether or not the width and length match within an allowable error range. In this case, it is determined whether or not the sheet feeder is in the auto-selection target in the sheet feeder setting.

  As a result, if there is a paper feeding device that stores printing paper of the same size within the tolerance range of the image data size (S104: Yes), the paper feeding device is used as a paper feeding device for printing. Determine (S105).

  On the other hand, if there is no paper feeder that stores printing paper of the same size within the allowable error range with the size of the image data (S104: No), the print settings included in the print data are referred to and the image is set. It is determined whether or not the selection of rotation is “auto” (S106).

  If the selection of image rotation is not “auto” (S106: No), a paper feeding device error is detected because there is no paper feeding device storing printing paper suitable for printing (S107). Thereby, it can prevent printing for the printing which is not intended.

  If the selection of image rotation is “auto” (S106: Yes), the paper that stores printing paper of the same size within the allowable error range and the size of the image data included in the print data if the image is rotated. It is determined whether there is a device (S108).

  As a result, if there is no paper feeding device that stores printing paper of the same size within the allowable error range and the size of the image data even when the image is rotated (S108: No), a printing paper suitable for printing is used. Since there is no stored paper feeding device, a paper feeding device error is determined (S107). Thereby, it can prevent printing for the printing which is not intended.

  If there is a paper feeder that stores printing paper of the same size within the allowable error range with the size of the image data included in the print data if the image is rotated (S108: Yes), the paper feeder is printed. The paper feeding device to be used is determined (S109). In this case, it is assumed that the image data is rotated to an appropriate angle and printing on the printing paper is performed.

  In the above description, for the sake of simplicity, the type of printing paper is not considered as a criterion for determining the paper feeding device. However, in actual operation, printing specified in the print settings is not considered. The coincidence between the paper type and the print paper type set by the paper feed device setting in the printer 20 is also used as a criterion for determining the paper feed device.

  As described above, the printer 20 of the present embodiment can automatically select a paper feeding device based on the size value of image data and the size value of printing paper in consideration of unit conversion.

10 ... PC
DESCRIPTION OF SYMBOLS 20 ... Printer 30 ... RIP apparatus 40 ... Computer network 110 ... Printer driver part 111 ... Print setting reception part 112 ... Print data generation part 113 ... Print data output part 210 ... Print data reception part 220 ... Print control part 221 ... Paper feed apparatus Determination unit 230 ... printing mechanism unit 240 ... paper feeding unit 241 ... first paper feeding device 242 ... second paper feeding device 243 ... third paper feeding device 244 ... fourth paper feeding device 250 ... operation receiving unit 251 ... paper feeding device Setting reception

Claims (5)

An image forming apparatus including one or a plurality of paper feeding devices,
Receiving means for receiving image data with a specified size value;
Paper feeding device setting accepting means for accepting setting of the size value of the printing paper stored in the paper feeding device;
Paper feeding device determining means for determining a paper feeding device that stores printing paper having the same size value as the received image data as a paper feeding device for paper feeding;
If the difference between the size value of the image data and the size value of the printing paper is within a predetermined allowable range value, the paper feeding device determination unit determines that the size value of the image data and the size value of the printing paper are An image forming apparatus characterized by being regarded as the same. The image forming apparatus according to claim 1,
If the image data is rotated and the size value of the image data and the size value of the printing paper can be considered to be the same, the paper feeding device determination unit supplies the paper feeding device storing the printing paper. An image forming apparatus, wherein the image forming apparatus is determined as a paper feeding device for performing paper. The image forming apparatus according to claim 1, wherein:
The image forming apparatus, wherein the predetermined allowable range value is determined based on a maximum error that may occur due to a rounding error in unit conversion with respect to the size value. The image forming apparatus according to any one of claims 1 to 3,
The image forming apparatus, wherein the predetermined allowable range value can be changed by a user. The image forming apparatus according to any one of claims 1 to 4, wherein
In the image data, a paper type is further specified,
The paper feeding device setting accepting unit further accepts a setting of a paper type of the printing paper stored in the paper feeding device,
The paper feeding device determination unit is designated in the paper type of the printing paper and the image data even when the size value of the image data and the size value of the printing paper can be regarded as the same. An image forming apparatus, wherein when a paper type is different, a paper feeding device storing the printing paper is not determined as a paper feeding device for feeding paper.