JP2008187528A - Image reader and image forming apparatus - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an image reader capable of performing accurate shading correction. <P>SOLUTION: The image reader 1 includes a white reference part 23 which is white, a read unit 20 which reads an image of a document 3 and an image of the white reference part 23, and a storage unit 42 which stores image data read by the read unit 20, and outputs image data of the document 3 after shading correction based upon white reference data generated according to image data of the white reference part 23. The image reader previously stores the storage unit 42 with the image data of the white reference part 23 read in a predetermined period such as a shipment period, and detects a staining amount of the white reference part 23 based upon a result of comparison between a high-frequency component of the image data of the white reference part 23 in the predetermined period and a high-frequency component of the image data of the white reference part 23 read right before the document 3 is read. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to an image reading apparatus that performs shading correction and an image forming apparatus using the image reading apparatus.

  A conventional image reading apparatus that performs shading correction is disclosed in Japanese Patent Application Laid-Open No. H10-228707. This image reading apparatus has a light source and an image sensor, and includes a reading unit that reads a document image by reflected light of light irradiated on the document. Further, a white white reference plate that can be read by the reading unit is provided.

  When reading of the document is instructed, the reading unit reads the image of the white reference plate, and then reads the document image. The image data of the original image is subjected to shading correction by the image data of the white reference plate, and the corrected image data is output.

  If dirt such as dust adheres to the white reference plate, the illuminance at that portion decreases. For this reason, when shading correction is performed, the relative illuminance relative to the white reference plate is high in the portion corresponding to the dirt on the document. As a result, white lines are generated in the sub-scanning direction in the output image data after shading correction. In the image reading apparatus, the white reference plate is disposed at a position where the focus of the optical system of the reading unit is shifted. For this reason, even if dirt adheres on the white reference plate, the dirt is blurred and caught. Thereby, the illuminance of the dirty portion can be made close to white, and the white line of the image data after shading correction can be prevented.

JP-A-6-178052

  However, according to the above-described conventional image reading apparatus, if the white reference plate becomes dirty, the illuminance of the dirty portion becomes low even if the optical system is blurred. For this reason, there is a problem that accurate shading correction cannot be performed.

  An object of the present invention is to provide an image reading apparatus capable of performing accurate shading correction and an image forming apparatus using the image reading apparatus.

  In order to achieve the above object, the present invention comprises a white white reference portion, a reading portion that reads a document image and an image of the white reference portion, and a storage portion that stores image data read by the reading portion, In an image reading apparatus that outputs shading corrected image data of a document based on white reference data formed in accordance with image data of the white reference portion, the image data of the white reference portion read at a predetermined time is previously stored. A high-frequency component stored in the storage unit and perpendicular to the document feeding direction of the image data of the white reference portion at the predetermined time and the document feeding direction of the image data of the white reference portion read immediately before reading the document. The amount of contamination of the white reference portion is detected based on a result of comparison with a high-frequency component in a direction perpendicular to.

  According to this configuration, the storage unit stores image data obtained by reading the white reference portion by the reading unit at a predetermined time when the white reference portion is not contaminated. When the reading of the document is instructed, the image of the white reference portion is read by the reading unit and stored in the storage unit, and then the document image is read. From the image data of the white reference portion at a predetermined time stored in the storage portion, a high frequency component having a spatial frequency in a direction perpendicular to the document feeding direction is extracted. From the image data of the white reference portion read immediately before the document, a high frequency component having a spatial frequency in a direction perpendicular to the document feeding direction is extracted. These high-frequency component data are compared, and the amount of dirt in the white reference portion is detected based on the comparison result. As a result, it is possible to perform processing such as cleaning of the white reference portion, prompting replacement, and stopping output. The image data of the document image is subjected to shading correction based on the white reference data formed from the image data of the white reference portion at the predetermined time or immediately before, and the corrected image data is output. The white reference portion may be plate-shaped or roller-shaped.

  According to the present invention, in the image reading apparatus configured as described above, a high-frequency component in a direction perpendicular to the document feed direction of the image data of the white reference portion at the predetermined time and the white reference portion read immediately before reading the document. It is characterized in that the amount of contamination of the white reference portion is detected by an integral value of a portion where the absolute value of the difference between the high-frequency component in the direction perpendicular to the document feed direction of the image data is larger than a predetermined threshold value.

  According to this configuration, the horizontal axis indicates the position on the white reference portion perpendicular to the document feed direction, the high frequency component of the image data of the white reference portion at a predetermined time, and the white reference portion read immediately before reading the document. On the graph with the vertical axis representing the difference from the high-frequency component of the image data, the total area of the portion protruding from the threshold is detected as the amount of dirt.

  According to the present invention, in the image reading apparatus configured as described above, a high-frequency component in a direction perpendicular to the document feed direction of the image data of the white reference portion at the predetermined time and the white reference portion read immediately before reading the document. It is characterized in that the amount of contamination of the white reference portion is detected by counting the number of pixels in which the difference between the high-frequency component in the direction perpendicular to the document feed direction of the image data is larger than a predetermined threshold value.

  According to this configuration, the horizontal axis indicates the position on the white reference portion perpendicular to the document feed direction, the high frequency component of the image data of the white reference portion at a predetermined time, and the white reference portion read immediately before reading the document. The total number of pixels protruding from the threshold on the graph with the vertical axis representing the difference from the high frequency component of the image data is detected as the amount of dirt.

  Further, the present invention is characterized in that, in the image reading apparatus having the above-described configuration, a notification is given when the amount of dirt in the white reference portion is larger than a predetermined amount. According to this configuration, when the white reference portion has a large amount of dirt, a notification for prompting cleaning or replacement, or a notification for inquiring whether to stop reading the document is performed.

  According to the present invention, in the image reading apparatus configured as described above, an image reading apparatus capable of reading both sides of a document, wherein the image on the upper surface of the document is read by the reading unit.

  According to the present invention, in the image reading apparatus configured as described above, the white reference portion is disposed to face the reading portion via a document.

  According to the present invention, in the image reading apparatus configured as described above, the predetermined time is a shipment time. According to this configuration, the image data of the white reference portion at the time of shipment of the image reading apparatus in which the dirt is not adhered on the white reference portion is stored in the storage portion.

  According to the present invention, in the image reading apparatus having the above-described configuration, the predetermined time can be set by a user. According to this configuration, an image of the white reference portion that is not contaminated is read by cleaning by a user or the like, and the image data is stored in the storage unit.

  According to another aspect of the present invention, there is provided an image forming apparatus including the above-described image reading apparatus, and forming an image based on shading-corrected image data output from the image reading apparatus.

  According to the present invention, the high-frequency component in the direction perpendicular to the document feeding direction of the image data of the white reference portion read at a predetermined time without contamination and the document feeding of the image data of the white reference portion read immediately before reading the document. By comparing the high-frequency component in the direction perpendicular to the direction, it is possible to easily detect the amount of dirt in the white reference portion. As a result, cleaning and replacement of the white reference portion can be promoted, and reading of the document can be stopped. Accordingly, it is possible to avoid the shading correction by the white reference portion where the amount of dirt increases and to perform accurate shading correction.

  Further, according to the present invention, the high-frequency component in the direction perpendicular to the document feeding direction of the image data of the white reference portion read at a predetermined time without contamination, and the document of the image data of the white reference portion read immediately before reading the document. The amount of contamination of the white reference portion can be easily detected by the integral value of the portion where the absolute value of the difference from the high frequency component in the direction perpendicular to the feed direction is larger than a predetermined threshold value.

  Further, according to the present invention, the high-frequency component in the direction perpendicular to the document feeding direction of the image data of the white reference portion read at a predetermined time without contamination, and the document of the image data of the white reference portion read immediately before reading the document. By counting the number of pixels in which the difference from the high-frequency component in the direction perpendicular to the feed direction has an absolute value larger than a predetermined threshold value, the amount of dirt in the white reference portion can be easily detected.

  Further, according to the present invention, since the notification is made when the amount of contamination of the white reference portion is larger than a predetermined amount, it is possible to prompt the cleaning or replacement of the white reference portion, and to inquire of stopping the reading of the document. Therefore, the convenience of the image forming apparatus can be improved.

  Further, according to the present invention, the image reading apparatus is capable of reading both sides of the document, and the image on the upper surface of the document is read by the reading unit, so that dirt is likely to adhere to the white reference portion facing upward. Can be detected easily and accurate shading correction can be performed.

  Further, according to the present invention, since the white reference portion is disposed opposite to the reading portion via the document, the stain is more easily adhered by sliding on the document. However, the amount of the stain can be easily detected to perform accurate shading correction. It can be carried out.

  Further, according to the present invention, since the predetermined time for reading the white reference portion in advance is the time of shipment, it is possible to reliably read the white reference portion without the stain and accurately detect the amount of stain.

  Further, according to the present invention, the predetermined time for reading the white reference portion in advance can be set by the user. Therefore, when the white reference portion is cleaned or replaced by the user, the white reference portion is surely free from dirt. Can be detected accurately.

  Embodiments of the present invention will be described below with reference to the drawings. FIG. 1 is a side sectional view showing an image reading apparatus according to an embodiment. In the image reading apparatus 1, a document conveying portion 1a is disposed above, and a main body portion 1b including a control unit 40 (see FIG. 2) is disposed below the document conveying portion 1a. In the drawing of the document conveying portion 1a, an inclined paper feed tray 2 is disposed at the upper right side, and a paper discharge tray 25 is disposed at the lower right side. A document 3 is placed on the paper feed tray 2, and a document whose image has been read is discharged to a paper discharge tray 25.

  Above the paper feed tray 2 is provided a paper feed roller 4 that contacts the original 3 and takes out the original. A rotating platen roller 9 is arranged on the left side of the document conveying portion 1a. Between the sheet feeding tray 2 and the platen roller 9 and between the platen roller 9 and the sheet discharge tray 25, a conveyance path 7 that includes conveyance rollers 5, 6, and 24 and conveys the document 3 is provided. The platen roller 9 reverses the original 3 fed from the paper feed tray 2 and guides it to the paper discharge tray 25. Further, the document 3 can be fed to the platen roller 9 one by one by the upper conveying rollers 5 and 6.

  Below the platen roller 9, a transparent plate 10 made of glass provided on the main body 1b is disposed to face the platen roller 9. A first reading unit 11 is disposed below the transparent plate 10 in the main body 1b. The first reading unit 11 includes a light source 12, reflection mirrors 13, 14, 15, a lens 16 and a CCD 17. The light source 12 is formed of a fluorescent lamp, and irradiates light on the document 3 disposed at the reading position 8 on the transparent plate 10. The light reflected from the surface of the document 3 is reflected by the reflection mirrors 13, 14, and 15 and guided to the CCD 17 through the lens 16. Thereby, the image of the lower surface (front surface) of the document 3 is read.

  A white white reference plate 18 is provided on the side of the transparent plate 10. The first reflection unit 11 is configured to be movable in the left-right direction in the figure, reflects the light emitted from the light source 12 by the white reference plate 18, and the image of the surface of the white reference plate 18 is read by the CCD 17. The image data of the document 3 read by the first reading unit 11 is subjected to shading correction by the image data of the white reference plate 18, and the corrected image data is output.

  A second reference unit 20 and a white reference roller 23 (white reference unit) composed of a white roller for conveyance are arranged opposite to the downstream side of the conveyance path 7 from the reading position 8. The second reading unit 20 has a CIS (Contact Image Sensor) 21 of an equal magnification optical system, and the CIS 21 has a built-in light source 22 composed of LEDs. The light emitted from the light source 22 irradiates the document 3 disposed on the white reference roller 23. The light reflected by the document 3 is guided to the CIS 21. Thereby, the image on the upper surface (back surface) of the document 3 is read.

  Further, the second reading unit 20 reflects the light emitted from the light source 22 by the white reference roller 23 before the document 3 is conveyed, and the image on the surface of the white reference roller 23 is read by the CIS 21. The image data of the document 3 read by the second reading unit 20 is subjected to shading correction by the image data of the white reference roller 23, and the corrected image data is output. The white reference roller 23 may be formed in a flat plate shape similar to the white reference plate 18, and a roller facing the second reading unit 20 may be provided separately.

  The document 3 on which both-side images are read by the first and second reading units 11 and 20 is discharged to the discharge tray 25 via the conveyance roller 24. A transparent glass plate or the like on which the document 3 can be placed may be provided on the main body 1b, and the document conveying unit 1a may be configured to be retractable from the glass plate. As a result, the original conveying section 1a is retracted, the original 3 is placed on the glass plate, and the moving first reading section 11 scans the original 3 in the sub-scanning direction to read the image on the lower surface of the original 3. it can.

  FIG. 2 is a block diagram showing the configuration of the image reading apparatus 1. The image reading apparatus 1 includes a control unit 40 that controls each unit. Amplifiers 31 and 33, A / D converters 32 and 34, an operation unit 41, and a storage unit 42 are connected to the control unit 40. The amplifiers 31 and 33 are connected to the CCD 17 and the CIS 21, respectively, and a gain adjustment signal is given from the control unit 40. As a result, the amplifiers 31 and 33 are subjected to AGC (Automatic Gain Control) by the control unit 40, and a gain value is set and calibration is performed. The amplifiers 31 and 33 amplify the output signals of the CCD 17 and the CIS 21 by adjusting the gain according to the set gain value.

  The A / D converters 32 and 34 convert image signals composed of analog signals amplified by the amplifiers 31 and 33, respectively, into digital signals. The operation unit 41 designates reading of a single-sided original or a double-sided original, and inputs the number of copies, paper size, and the like. The storage unit 42 stores an operation program of the image reading apparatus 1, a calculation result by the control unit 40, image data read by the CCD 17 and the CIS 21, and the like.

  Next, an operation for reading an image of a document by the first and second reading units 11 and 20 will be described. At the time of shipment of the image reading apparatus 1, image data obtained by reading the white reference plate 18 with the light source 12 turned off is stored in the storage unit 42 in advance. This image data becomes black reference data (hereinafter referred to as “black reference data”) when the image data on the lower surface of the document 3 is subjected to shading correction. White reference data for shading correction (hereinafter referred to as “white reference data”) is read and held by the white reference plate 18 immediately before reading the document 3.

  The image data of the white reference roller 23 is stored in the storage unit 42 in advance when the image reading apparatus 1 is shipped. FIG. 3 is a flowchart showing this operation. In step # 51, the light source 22 is turned off. In step # 52, the image of the white reference roller 23 is read by the second reading unit 20. In step # 53, the read image data of the white reference roller 23 is stored in the storage unit 42. This image data becomes black reference data when the image data on the upper surface of the document 3 is subjected to shading correction.

  In step # 54, the light source 22 is turned on. In step # 55, the image of the white reference roller 23 is read by the second reading unit 20. The image data of the white reference roller 23 read in step # 56 is stored in the storage unit 42. This image data becomes the initial image data (hereinafter referred to as “initial data”) of the white reference roller 23 for forming white reference data for shading correction.

  FIG. 4 is a flowchart showing an operation of reading an image on the front surface (lower surface) of the document 3 by the first reading unit 11. When the operation unit 41 instructs to read the document 3, the light source 12 is turned on in step # 11. In step # 12, the image of the white reference plate 18 is read by the first reading unit 11. In step # 13, the read image data of the white reference plate 18 is stored in the storage unit. This image data becomes white reference data at the time of shading correction.

  In step # 14, the lower surface of the document 3 placed at the reading position 8 by the conveyance is read by the first reading unit 11. In step # 15, the black reference data and the white reference data stored in the storage unit 42 are extracted, and the image data of the document 3 is subjected to shading correction based on Expression (1). Thereby, correction data indicating relative illuminance with respect to the white reference plate 18 is obtained. In step # 16, image data composed of the correction data is output.

Correction data =
(Original image data-black reference data) / (white reference data-black reference data) (1)

  FIG. 5 is a flowchart showing an operation of reading an image on the back surface (upper surface) of the document 3 by the second reading unit 20. In step # 21, the light source 22 is turned on. In step # 22, the image of the white reference roller 23 is read by the second reading unit 20. In step # 23, the read image data of the white reference plate 28 is stored in the storage unit 42. This image data becomes image data (hereinafter referred to as “immediate data”) of the white reference roller 23 read immediately before reading the document image, and is used to form white reference data for shading correction.

  In step # 24, the spatial frequency of the initial data is frequency-separated. FIG. 6 is a diagram showing initial data. The vertical axis represents the illuminance of the white reference roller 23, and the horizontal axis represents the position in the direction perpendicular to the document feeding direction of the CIS 21. FIGS. 7 and 8 show diagrams in which the spatial frequency of the initial data is separated into a low frequency component and a high frequency component, respectively. The vertical axis represents the illuminance of the white reference roller 23, and the horizontal axis represents the position in the direction perpendicular to the document feeding direction of the CIS 21.

  In step # 25, the spatial frequency of the immediately preceding data is frequency-separated. FIG. 9 is a diagram showing the immediately preceding data. The vertical axis represents the illuminance of the white reference roller 23, and the horizontal axis represents the position in the direction perpendicular to the document feeding direction of the CIS 21. FIG. 10 and FIG. 11 show diagrams in which the spatial frequency of the immediately preceding data is separated into a low frequency component and a high frequency component in a direction perpendicular to the document feed direction. The vertical axis represents the illuminance of the white reference roller 23, and the horizontal axis represents the position in the direction perpendicular to the document feeding direction of the CIS 21.

  Note that the low frequency components of the initial data and the immediately preceding data can be obtained by moving average in units of a predetermined number of pixels. Further, the high frequency component can be obtained by subtracting the low frequency component from the original data. The initial data and the immediately preceding data may be subjected to frequency analysis and separated into a low frequency component and a high frequency component with a predetermined frequency as a threshold.

  In step # 26, white reference data used for shading correction is created. The white reference data is obtained by superimposing the high-frequency component in the direction perpendicular to the document feed direction of the initial data shown in FIG. 8 and the low-frequency component in the direction perpendicular to the document feed direction of the previous data shown in FIG. It is done. FIG. 12 shows the white reference data. The vertical axis represents the illuminance of the white reference roller 23, and the horizontal axis represents the position in the direction perpendicular to the document feeding direction of the CIS 21.

  Dirt adhering to the white reference roller 23 appears as a high frequency component of the spatial frequency of the image data read by the white reference roller 23. Further, the change with time of the illuminance of the light source 22 appears as a low frequency component of the spatial frequency of the image data read by the white reference roller 23. Therefore, the shading correction is performed based on the white reference data obtained by superimposing the high frequency component of the initial data and the low frequency component of the immediately preceding data, thereby removing the influence of the temporal change of the light source 22 and the contamination of the white reference roller 23. it can.

  In step # 27, the amount of dirt on the white reference roller 23 is detected. First, the difference between the high-frequency component of the initial data shown in FIG. 8 and the high-frequency component of the immediately preceding data shown in FIG. FIG. 13 shows the difference between the high frequency component of the initial data and the high frequency component of the immediately preceding data. The vertical axis is the difference between the high frequency component of the initial data and the high frequency component of the immediately preceding data, and the horizontal axis is the position in the direction perpendicular to the document feed direction of the CIS 21.

  In the figure, an area (shaded portion) obtained by integrating a portion having an absolute value larger than a predetermined threshold S is determined as the amount of dirt on the white reference roller 23. Alternatively, the number of pixels having an absolute value larger than the threshold value S may be counted to determine the amount of dirt on the white reference roller 23.

  In step # 28, it is determined whether or not the amount of contamination of the white reference roller 23 detected in step # 27 is greater than a predetermined value. That is, in this embodiment, the influence of the stain on the white reference roller 23 can be removed, but if the amount of dirt is extremely large, the influence of the stain cannot be sufficiently removed on the white reference data. Therefore, it is determined whether or not the amount of dirt has an influence on the white reference data.

  If the amount of dirt on the white reference roller 23 is not greater than the predetermined value, the process proceeds to step # 31. If the amount of dirt on the white reference roller 23 is larger than the predetermined value, it is notified in step # 29 that the amount of dirt is large. This prompts cleaning or replacement of the white reference roller 23.

  In addition, the user is inquired at the same time whether or not to stop reading the document 3. In step # 30, it is determined whether or not there is an instruction to stop reading the document 3. If there is an instruction to stop reading the document 3, the process is terminated. If there is an instruction to force reading of the document 3, the process proceeds to step # 31.

  Note that when the amount of dirt exceeds a predetermined amount, the notification of the fact may be notified, and then the document reading may be stopped and the process may be terminated. Further, since the white reference roller 23 is a rotating roller, when the amount of dirt exceeds a predetermined amount, the white reference roller 23 is rotated to change the reading position by the second reading unit 20, and the steps # 22 and after are repeated again. May be.

  In step # 31, the upper surface of the document 3 disposed below the second reading unit 20 by the conveyance is read by the second reading unit 20. In step # 32, the image data on the upper surface of the document 3 is subjected to shading correction based on the above equation (1), and correction data indicating relative illuminance with respect to the white reference roller 23 is obtained. In step # 33, image data composed of the correction data is output.

  According to the present embodiment, the high-frequency component of the image data of the white reference roller 23 (white reference portion) read at the time of shipment without contamination and the high-frequency component of the image data of the white reference roller 23 read immediately before reading the document 3. Since the shading correction of the image data of the original image is performed by the second reading unit 20 based on the white reference data superimposed with the white reference data, the white reference data is the image data of the white reference roller 23 read immediately before the original 3 is read. Thus, the high-frequency component due to the dirty portion is removed and the low-frequency component that changes with time such as the illuminance of the light source 22 is retained. Accordingly, accurate shading correction can be performed by eliminating the influence of dirt on the white reference roller 23.

  Further, the white reference roller can be easily compared by comparing the high-frequency component of the image data of the white reference roller 23 read at the time of shipment without contamination with the high-frequency component of the image data of the white reference roller 23 read immediately before reading the document. 23 can be detected. As a result, cleaning and replacement of the white reference roller 23 can be promoted, and reading of the document can be stopped. Accordingly, it is possible to avoid the shading correction by the white reference roller 23 having a large amount of dirt and perform accurate shading correction.

  Although the initial data is acquired at the time of shipment of the image forming apparatus 1, the user may be able to acquire the initial data at a desired time by setting operation of the operation unit 41. As a result, when the white reference roller 23 is cleaned or replaced by the user, the white reference roller 23 without contamination can be reliably read and accurate shading correction can be performed.

  In addition, the difference between the high frequency component of the image data of the white reference roller 23 read at a predetermined time without contamination and the high frequency component of the image data of the white reference roller 23 read immediately before reading the document 3 is a predetermined threshold value S. The amount of dirt on the white reference roller 23 can be easily detected based on the integral value of the portion where the absolute value becomes larger than that.

  In addition, since the notification is made when the amount of dirt on the white reference roller 23 is larger than a predetermined amount, cleaning and replacement of the white reference roller 23 can be urged, and an inquiry to stop reading the original can be made. Therefore, the convenience of the image forming apparatus 1 can be improved.

  Further, since the second reading unit 20 reads the upper surface of the document 3, the white reference roller 23 faces upward. For this reason, dirt easily adheres to the white reference roller 23. In addition, since the white reference roller 23 is disposed opposite to the second reading unit 20 via the document 3, the white reference roller 23 slides on the document 3 and dirt is more easily attached. Therefore, according to this embodiment, the amount of dirt can be easily detected and accurate shading correction can be performed.

  The white reference plate 18 is isolated from the document conveying portion 1a and faces downward, so that the dirt is difficult to adhere. For this reason, the image data on the lower surface of the document 3 is subjected to shading correction using the image data of the white reference plate 18 read immediately before reading the document as white reference data. Thereby, control can be simplified.

  However, when the influence of the dirt adhering to the white reference plate 18 is large, the high frequency component of the image data of the white reference plate 18 read at a predetermined time without the dirt and the original, as in the case of the upper surface of the original 3. It is preferable to perform shading correction of the image data of the original image by the first reading unit 11 based on the white reference data superimposed with the low frequency component of the image data of the white reference plate 18 read immediately before reading 3.

  In this embodiment, the image reading apparatus 1 is described. However, the image reading apparatus 1 is an image forming apparatus such as a copying machine that includes the image reading apparatus 1 and forms an image based on image data output from the image reading apparatus 1. Also good.

  The present invention can be used in an image reading apparatus and an image forming apparatus that perform shading correction.

1 is a side sectional view showing an image forming apparatus according to an embodiment of the present invention. 1 is a block diagram showing a configuration of an image forming apparatus according to an embodiment of the present invention. 6 is a flowchart showing processing for acquiring an initial value for reading the lower surface of a document of the image forming apparatus according to the embodiment of the present invention. 6 is a flowchart showing an operation of reading the upper surface of a document of the image forming apparatus according to the embodiment of the present invention. 6 is a flowchart showing an operation of reading the upper surface of a document of the image forming apparatus according to the embodiment of the present invention. The figure which shows the initial data of the white reference board of the image forming apparatus of embodiment of this invention. The figure which shows the low frequency component of the initial data of the white reference board of the image forming apparatus of embodiment of this invention. The figure which shows the high frequency component of the initial data of the white reference board of the image forming apparatus of embodiment of this invention. The figure which shows the data immediately before the white reference board of the image forming apparatus of embodiment of this invention. The figure which shows the low frequency component of the data immediately before the white reference board of the image forming apparatus of embodiment of this invention. The figure which shows the high frequency component of the data immediately before the white reference board of the image forming apparatus of embodiment of this invention. 6 is a diagram showing white reference data at the time of reading by the second reading unit of the image forming apparatus according to the embodiment of the present invention. FIG. FIG. 6 is a diagram for detecting the amount of dirt on the white reference plate during reading by the second reading unit of the image forming apparatus according to the embodiment of the present invention.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Image forming apparatus 1a Original conveyance part 1b Main body part 2 Paper feed tray 3 Original document 4 Feed roller 5, 6, 24 Conveyance roller 7 Conveyance path 8 Reading position 9 Platen roller 10 Transparent plate 11 First reading part 12, 22 Light source 13 , 14, 15 Reflection mirror 16 Lens 17 CCD
18 White reference plate 20 Second reading unit 21 CIS
23 White reference roller 25 Discharge tray 31, 33 Amplifier 32, 34 A / D converter 40 Control unit 41 Operation unit 42 Storage unit

Claims (9)

  A white white reference portion; a reading portion that reads an original image and an image of the white reference portion; and a storage portion that stores image data read by the reading portion, and is formed according to the image data of the white reference portion. In the image reading device that outputs the image data of the document after shading correction based on the white reference data, the image data of the white reference portion read at a predetermined time is stored in the storage unit in advance, Comparison result between the high-frequency component in the direction perpendicular to the document feed direction of the image data of the white reference portion and the high-frequency component in the direction perpendicular to the document feed direction of the image data of the white reference portion read just before reading the document An image reading apparatus that detects the amount of contamination of the white reference portion based on the above.   The high-frequency component in the direction perpendicular to the document feeding direction of the image data of the white reference portion at the predetermined time and the high-frequency component in the direction perpendicular to the document feeding direction of the image data of the white reference portion read immediately before reading the document. 2. The image reading apparatus according to claim 1, wherein a stain amount of the white reference portion is detected based on an integral value of a portion where the absolute value of the difference between the reference value and the difference is larger than a predetermined threshold value.   The high-frequency component in the direction perpendicular to the document feeding direction of the image data of the white reference portion at the predetermined time and the high-frequency component in the direction perpendicular to the document feeding direction of the image data of the white reference portion read immediately before reading the document. 2. The image reading apparatus according to claim 1, wherein the number of pixels whose absolute value is greater than a predetermined threshold is counted to detect the amount of contamination of the white reference portion.   The image reading apparatus according to claim 1, wherein the image reading apparatus is notified when the amount of dirt in the white reference portion is larger than a predetermined amount.   The image reading apparatus according to claim 1, wherein the image reading apparatus is capable of reading both sides of a document, and reads an image on an upper surface of the document by the reading unit.   The image reading apparatus according to claim 5, wherein the white reference unit is disposed to face the reading unit via a document.   The image reading apparatus and the image forming apparatus according to claim 1, wherein the predetermined time is a shipping time.   8. The image reading apparatus and the image forming apparatus according to claim 1, wherein the predetermined time can be set by a user.   An image forming apparatus comprising the image reading apparatus according to claim 1, wherein an image is formed based on shading-corrected image data output from the image reading apparatus.

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