JP2005223562A - Image reading apparatus - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an image reading apparatus capable of easily acquiring proper shading for excellently reading an image even when part of an outer circumferential face of a shading roller gets dirt. <P>SOLUTION: The image reading apparatus 100 is provided with: a discrimination means for discriminating the presence of dirt in a read region on the basis of read data acquired by an image read means 3 for reading an image of the read region corresponding to one or more main scanning lines on an outer circumferential face of a shading roller 10; and a control means for storing the read data of the read region to a memory 38 as shading correction data S when the discrimination means discriminates that no dirt exists in the read region and allows the image read means 3 to read an image of a read region different from the read region above by turning the shading roller 10 by a prescribed angle when the control means discriminates that the read region gets dirt. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

  The present invention relates to an image reading apparatus, and more particularly to an image reading apparatus that performs shading correction on image data of a read original document based on shading correction data acquired by reading an image of an outer peripheral surface of a shading roller. .

  In a scanner machine, a facsimile machine, a copier, and a complex machine of these, the original is automatically conveyed along the original conveyance path, and the original is read by the two image reading units arranged along the original conveyance path. There are some which read the image data of both sides. For example, in the copier / facsimile multifunction peripheral 900 shown in FIG. 5, the original on the original tray 901 is transferred to the original conveyance path 902 and passes through the reading position P1, and the original is read by the movable surface reading unit 903. When the image data on the front side is read and further passes through the reading position P2 downstream thereof, the image data on the back side of the document is read by the fixed back side reading unit 905 provided in the document pressing cover 904. It is discharged to a discharge tray 906.

  The front side reading unit 903 and the back side reading unit 905 that respectively read the image data of the front and back sides of the original are photoelectrically converted by the line sensor to reflect light reflected from the light source to the original, and the original image data is subjected to main scanning. Reading line by line. When the image data of the document is read using the line sensor in this manner, output unevenness occurs in the image data due to the light amount distribution of the light source, the sensitivity variation for each pixel of the line sensor, and the like, so that shading correction is performed. In the surface reading unit 903, a scanning unit (not shown) moves, reads an image of a shading plate serving as a white reference image, acquires shading correction data, and performs shading correction based on the shading correction data. .

  On the other hand, the back surface reading unit 905 is difficult to be provided due to structural limitations, and is fixedly provided in the document pressing cover 904, and reads the image data of the document by a contact image sensor. In general, the outer peripheral surface of the shading roller 907 is formed in white, and the back surface reading unit 905 reads the image of the outer peripheral surface as a white reference image and acquires shading correction data. The shading roller 907 is not only used as a white reference image for acquiring shading correction data, but also transports a document in close contact with the back surface reading unit 905. For this reason, if a part of the toner or paper dust on the document conveyed in close contact adheres to the outer peripheral surface of the shading roller 907, proper shading correction data for good image reading cannot be acquired. There was a problem.

  As an image reading device devised in view of this, Patent Document 1 reads an image corresponding to two main scanning lines from the outer peripheral surface of a shading roller, and sets the maximum value of the first pixel data in advance. When the measured reference value is exceeded, the second pixel data is normalized and acquired as shading correction data based on the highest value of the first pixel data, and when it is below, the user is warned that the shading roller is dirty. An image reading apparatus is disclosed.

Further, in Patent Document 2, even if a part of the outer peripheral surface of the shading roller is dirty, an image in a certain range of the outer peripheral surface of the shading roller is read in order to obtain shading correction data from the unclean part. The obtained read data is divided into a predetermined number of blocks in the sub-scanning direction, the average value of the output values of the pixel data of each line is obtained for each block, and the highest value of each average value is obtained as shading correction data An apparatus is disclosed.
Japanese Patent Laid-Open No. 11-4948 JP 2002-152510 A

  However, in the image reading apparatus of Patent Document 1, when the first outer peripheral surface of the shading roller is dirty, even if the other portion of the outer peripheral surface of the shading roller is not dirty, the shading correction is performed. There was a problem that data could not be acquired and the image data could not be read until the user cleaned the outer peripheral surface of the shading roller.

  Further, the image reading apparatus of Patent Document 2 has a problem that it takes time to obtain appropriate shading correction data because it needs to perform complicated data processing after reading a wide range of read data.

  The present invention has been made to solve such a problem, and even when a part of the outer peripheral surface of the shading roller is dirty, it is possible to easily obtain an appropriate shading for good image reading. An object is to provide a reader.

  In order to achieve the object, an image reading apparatus according to claim 1 includes an image reading unit that reads image data of a document conveyed along a document conveyance path for each main scanning line, and the image reading unit. A shading roller rotatably disposed at an opposing position across the document transport path, and a document read by the image reading unit based on shading correction data stored in a memory by reading an image of the outer peripheral surface of the shading roller An image reading apparatus comprising: a shading correction unit that performs shading correction on the image data; and the image reading unit outputs an image of a reading region corresponding to one or a plurality of main scanning lines on the outer peripheral surface of the shading roller. A determination means for determining the presence or absence of contamination in the reading area based on the read data obtained by reading; When it is determined that there is no dirt in the reading area, the reading data of the reading area is stored in the memory as the shading correction data, and when the determination means determines that the reading area is dirty, the shading Control means for rotating the roller by a predetermined angle and causing the image reading means to read an image in a reading area different from the reading area to acquire read data.

  According to a second aspect of the present invention, in the image reading apparatus according to the first aspect, the determination unit is configured to determine whether a maximum deviation between adjacent pixel data of the read data exceeds a predetermined value. , And determining whether the reading area is dirty.

  The image reading apparatus according to claim 3, wherein in the image reading apparatus according to claim 1 or 2, when the determination unit determines that the predetermined number of reading areas are dirty, a notification unit that notifies the fact. It is characterized by having.

  According to the image reading apparatus of the first aspect, when the determination unit determines that the reading area of the shading roller is dirty, the image reading unit rotates the shading roller by a predetermined angle and reads different from the reading area. Since the image of the area is read and the read data is acquired, even if the read area read by the image reading means is dirty, the read data obtained by reading the image of the read area without the dirt can be easily used as the shading correction data. Therefore, it is possible to perform good image reading.

  According to the image reading apparatus of the second aspect, the determination unit determines whether the reading area is dirty based on whether the maximum deviation between adjacent pixel data of the reading data exceeds a predetermined value. It is possible to easily determine whether the reading area is dirty.

  According to the image reading apparatus of the third aspect, when the determination unit determines that the predetermined number of reading areas are dirty, the notification unit notifies that fact, so the predetermined number of the outer peripheral surface of the shading roller If appropriate shading correction data for good image reading cannot be obtained from any of the reading areas, it is possible to notify the user and prompt the user to clean the outer peripheral surface of the shading roller. Further, since it is clear that proper shading correction data for good image reading can be acquired until the notification means notifies, the user does not need to clean the outer peripheral surface of the shading roller until then.

  Hereinafter, a case where the image reading apparatus according to the embodiment of the present invention is applied to a multi-function peripheral having a copy function and a facsimile function will be described with reference to the drawings. As shown in FIG. 1, an upper part of the copy / facsimile multifunction peripheral (image reading apparatus) 100 is an automatic original with respect to an original placing table 101 functioning as a flat bed scanner (hereinafter referred to as “FBS”). A document presser cover 102 provided with an auto document feeder (hereinafter referred to as “ADF”) 1 as a transport mechanism is pivotally supported so as to be freely opened and closed. When the document conveyed by the ADF 1 passes through the reading position P1, the image data on the front surface is read by the front surface reading unit 2, and when the document passes through the reading position P2, the image data on the back surface is read by the back surface reading unit 3. It is supposed to be.

  A document holding cover 102 includes a document tray 4 that carries a document, a horizontally-oriented U-shaped document conveyance path 5, a discharge tray 6 that discharges the conveyed document, and a document on the document tray 4 for document conveyance. A paper feed roller 7 that feeds into the path 5, a transport roller 8 that nips and transports the document in the document transport path 5, a paper discharge roller 9 that is provided near the exit of the document transport path 5, and a reading position P2. The ADF 1 automatically includes a back side reading unit 3 that reads image data on the back side of the document that is transported and a shading roller 10 that is rotatably disposed at a position opposite to the back side reading unit 3 across the document transport path 5. Equipped as a document transport mechanism.

  The back side reading unit 3 functions as an image reading unit that reads image data of a document conveyed along the document conveyance path 5 for each main scanning line. The back side reading unit 3 is a fixed image reading unit using a contact image sensor (hereinafter referred to as “CIS”) as a line sensor, and includes a light source 11 for irradiating light on a document and a document. A converging fiber 12 for converging the reflected light in a predetermined direction, a photoelectric conversion element 13 for converting the converged light into an electric signal and outputting it, and a platen glass 14 to which the document is closely attached. In CIS, since the depth of field is generally shallow, as shown in FIG. 2A, the back surface reading unit 3 is in a state where a document conveyed through the reading position P2 is brought into close contact with the platen glass 14 by the shading roller 10 and is nipped. The image data is read by. The shading roller 10 is made of silicon rubber, silicon sponge, foamed urethane or the like, and at least the outer peripheral surface thereof is white because it becomes a white reference image for obtaining the shading correction data S. The shading roller 10 is rotated by a shading roller drive motor 31 (see FIG. 3), and when the document transported through the document transport path 5 passes the reading position P2, the document is pressed against the platen glass 14 and brought into close contact therewith. At the same time, it is conveyed at a predetermined speed. When the document does not pass through the reading position P2, the shading roller 10 is in a state where a part of the outer peripheral surface thereof is in close contact with the platen glass 14 at the reading position P2, as shown in FIG. . In this state, reflected light of the light irradiated from the light source 11 to the closely contacted outer peripheral surface of the shading roller 10 is photoelectrically converted by the photoelectric conversion element 13, and a reading area corresponding to one main scanning line on the outer peripheral surface of the shading roller 10. That is, read data obtained by reading an image from one line in the main scanning direction is obtained as shading correction data S for image data obtained by reading the back side of the document. Based on the shading correction data S acquired in this way, the image data of the document read by the back surface reading unit 3 is caused by unevenness in the light amount distribution of the light source 11 or sensitivity variation for each pixel of the photoelectric conversion element 13. The shading correction is performed by normalizing the variation in the density of the pixel data for each pixel.

  The document table 101 is provided with a transparent platen glass 16 on the top surface of a substantially rectangular parallelepiped casing 15, and the front surface reading unit 2 is built in the casing 15. The surface reading unit 2 includes a light source 17 that irradiates light on a document, a plurality of reflection mirrors 18 that guide reflected light from the document in a predetermined direction, a condensing lens 19 that converges the reflected light, and the convergent light. Is a reading unit of a reduction optical system including a charge coupled device (hereinafter referred to as “CCD”) 20 that converts the signal into an electric signal and outputs the electric signal. It is disposed in a scanning unit 21 that reciprocates horizontally with respect to the platen glass 16 by a driving mechanism. When reading the image data of the document as the FBS, the front surface reading unit 2 configured in this way scans the document on the platen glass 16 while the scanning unit 21 moves horizontally with respect to the platen glass 16, and from the document. The reflected light is guided to the CCD 20 to form an image. When reading the image data on the surface of the document conveyed by the ADF 1, the scanning unit 21 forms an image under the platen glass 22 by guiding reflected light from the document passing through the reading position P 1 to the CCD 20 by the ADF 1. Further, a shading plate 23 is provided as a guide for bringing the document passing the reading position P1 close to the platen glass 22. The shading plate 23 has at least a surface facing the platen glass 22 formed on a white surface by applying a white tape or painting white. The surface reading unit 2 reads an image of the white surface of the shading plate 23 as a white reference image, thereby obtaining shading correction data for image data obtained by reading the surface of the document. Based on the shading correction data acquired in this way, the image data of the document read by the front surface reading unit 2 is changed for each pixel due to unevenness in the light amount distribution of the light source 17 or variation in sensitivity of each pixel of the CCD 20. The shading correction is performed by normalizing the variation in the density of the pixel data.

  When the copy / facsimile multifunction peripheral 100 reads the image data on both sides of the document using the ADF 1, the document on the document tray 4 is sent to the document transport path 5 by the paper feed roller 7 and read by the transport roller 8. The image data on the front side of the document is read by the front surface reading unit 2 after being transported to the position P1, and further the image data on the back surface of the document is read by the back surface reading unit 3 by being transported to the reading position P2 by the transport roller 8. The paper is discharged to the paper discharge tray 6 by the roller 8. When reading image data of a document placed by the user on the platen glass 16, the document is pressed by the document pressing cover 102, and the scanning unit 21 of the surface reading unit 2 is placed horizontally with respect to the platen glass 16. By scanning the document while moving, the image data of the document is read.

  FIG. 3 is a block diagram showing an electrical configuration of the copy / facsimile multifunction peripheral 100 whose upper part is shown in FIG. The copy / facsimile multifunction peripheral 100 includes a control unit (MPU: Microprocessing Unit) 30, the back side reading unit 3, the front side reading unit 2, a shading roller driving motor 31, an analog / digital converter 32, an image processing unit 33, and a recording unit. 34, an operation unit 35, a notification unit 36, a ROM (Read Only Memory) 36, a RAM (Random Access Memory) 37, an image memory 39, a codec (CODEC: Coder and Decoder) 40, a modem 41, and an NCU (Network Control Unit) 42 The components constituting the copy / facsimile multifunction peripheral 100 are communicably connected by a bus 43.

  The control unit 30 is connected to each unit constituting the copy / facsimile multifunction peripheral 100 via the bus 43, and controls the processing operation of each unit. The back side reading unit 3 reads image data on the back side of the document passing through the reading position P2 for each main scanning line based on a control signal from the control unit 30, and outputs it as analog image data. Further, the back surface reading unit 3 reads an image of the reading area on the outer peripheral surface of the shading roller 10 based on a control signal from the control unit 30 and outputs it as analog read data. The surface reading unit 2 reads image data on the surface of the document placed on the platen glass 16 or the document passing through the reading position P1 for each main scanning line based on a control signal from the control unit 30, and outputs an analog image. Output as data. Further, the front surface reading unit 2 reads an image of the white surface of the shading plate 23 based on a control signal from the control unit 30 and outputs it as analog read data. The shading roller drive motor 31 rotates the shading roller 10 based on a control signal from the control unit 30.

  The analog / digital converter 32 converts the analog image data and analog read data output from the back side reading unit 3 or the front side reading unit 2 into digitized image data and read data, respectively. The image processing unit 33 performs image data processing such as shading correction, shift / line correction, and binarization on the image data of the original read by the back side reading unit 3 or the front side reading unit 2. The recording unit 34 records an image of the image data stored in the image memory 39 on a recording sheet. As a recording method in the recording unit 34, various recording methods such as an electrophotographic method and an ink jet recording method can be used.

  The operation unit 35 includes various operation keys linked with the notification unit 36, such as a start key for instructing start of reading of a document, a numeric keypad for inputting the number of copies, and a cursor key for performing various settings. . The notification unit 36 is a part for notifying the user of various information such as an operation state and a setting state of the copy / facsimile multifunction peripheral 100, and a liquid crystal display panel 45 for displaying characters, figures, and the like. Are provided with an LED lamp 46 for displaying the state of the copy / facsimile multifunction peripheral 100, a speaker 47 for emitting a predetermined warning sound and the like to notify the user.

  The ROM 37 is a part that stores various programs for controlling the operation of each unit constituting the copy / facsimile multifunction peripheral 100 by the control unit 30. For example, the shading correction program 48, the stain determination program 49, and the shading correction data acquisition A program 50 is stored. The RAM 38 stores various data such as setting information and operation information used for processing operations of the copy / facsimile multifunction peripheral 100 in a readable and writable state. The RAM 38 is provided on the outer peripheral surface of the shading roller 10 when the maximum deviation between the shading correction data S acquired by the back surface reading unit 3 reading the image of the outer peripheral surface of the shading roller 10 and the adjacent pixel data of the read data exceeds. The threshold value P that the control unit 30 determines that the reading area is dirty, and the upper limit of the number of rotations that the control unit 30 determines that the reading area on the outer peripheral surface of the shading roller 10 is dirty and rotates the shading roller 10. Is stored.

  The shading correction program 48 is a program for causing the image processing unit 33 to perform shading correction on the image data on the back side of the document read by the back side reading unit 3 based on the shading correction data S stored in the RAM 38. It is. In the present invention, the control unit 30, the shading correction program 48, and the image processing unit 33 that operates in accordance with the control unit 30, the shading correction data S stored in the RAM 38 when the back surface reading unit 3 reads the image of the outer peripheral surface of the shading roller 10. Functions as shading correction means for performing shading correction on image data of a document read based on the above.

  The stain determination program 49 is a program for the control unit 30 to perform processing for determining whether the reading area on the outer peripheral surface of the shading roller 10 read by the back surface reading unit 3 is dirty. In the present invention, the reading unit 3 reads the image of the reading area corresponding to one main scanning line on the outer peripheral surface of the shading roller 10 by the control unit 30, the dirt determination program 49, and the threshold value P. Based on the data, it functions as a determination means for determining whether the reading area is dirty. The pixel that is output from each pixel of each photoelectric conversion element 13 when the control unit 30 reads the image of the reading area on the outer peripheral surface of the shading roller 10 at the reading position P2 by the back surface reading unit 3 by the dirt determination program 49. Based on the read data obtained by digitizing the data by the analog / digital converter 32, it is determined whether or not the reading area on the outer peripheral surface of the shading roller 10 is dirty.

  Whether or not the reading area on the outer peripheral surface of the shading roller 10 is soiled is determined by whether the maximum deviation between adjacent pixel data of the read data obtained by reading the image of the reading area on the outer peripheral surface of the shading roller 10 exceeds a predetermined value. It is preferred to be based on whether or not. For example, by comparing output values between adjacent pixel data of read data or between adjacent pixel data separated by a few pixels, the maximum deviation between the pixel data exceeds the threshold value P. In this case, it is determined that the reading area on the outer peripheral surface of the shading roller 10 is dirty, and when it is equal to or less than the threshold value P, it is determined that the reading area on the outer peripheral surface of the shading roller 10 is not dirty. Further, when the minimum value of the pixel data of the read data is less than the minimum reference value (not shown) stored in the RAM 38, it is determined that the reading area on the outer peripheral surface of the shading roller 10 is dirty, and the minimum reference value In the case described above, it may be determined that the reading area on the outer peripheral surface of the shading roller 10 is not soiled. Note that the control unit 30 determines the reading area in a range corresponding to the size of the document to be read based on an input signal from a document detection sensor (not shown) that detects the document placed on the document tray 4. It is only necessary to determine the presence or absence of contamination in the reading area only for the read data obtained by reading the image.

  The shading correction data acquisition program 50 is a program for the control unit 30 to perform processing for acquiring the shading correction data S. In the present invention, when the control unit 30 and the shading correction data acquisition program 50 determines that the reading area is not contaminated, the reading data of the reading area is stored in the RAM 38 as the shading correction data S. When the determination unit determines that the reading area is dirty, the shading roller 10 is rotated by a predetermined angle to cause the back surface reading unit 3 to read an image in a reading area different from the reading area to acquire read data. It functions as a control means.

  The image memory 39 temporarily stores the read image data and the image data received by facsimile. The codec 40 encodes (decodes) image data corresponding to a predetermined protocol. The modem 41 is an ITU-T (International Telecommunication Union Telecommunication Standardization Sector) recommendation V.3. Modulate and demodulate transmitted / received data according to the 34 standard or similar. The NCU 42 is a line network control device that controls a telephone line to place or cut a telephone call, and is connected to a PSTN (Public Switched Telephone Network) 44. The copy / facsimile multifunction peripheral 100 having the above-described configuration is a copy function that records an image of image data of a document read by the back side reading unit 3 or the front side reading unit 2 on a sheet, and an image with an external device via the PSTN 44. A facsimile transmission / reception function for transmitting and receiving data by facsimile and a facsimile recording function for recording an image of image data received by facsimile on a sheet are provided.

  A processing operation for obtaining the shading correction data S in the copy / facsimile multifunction peripheral 100 shown in FIGS. 1 and 3 will be described based on the flowchart shown in FIG. An instruction to read image data on both sides of a document placed on the document tray 4 when the power of the copy / facsimile multifunction peripheral 100 is turned on or when a start key (not shown) of the operation unit 33 is pressed. When there is an instruction to acquire shading correction data S (S1: YES), the control unit 30 sets the number of rotations k to 0 (S2). Then, the back side reading unit 3 reads an image of the reading area on the outer peripheral surface of the shading roller 10 to obtain read data (S3). Based on the read data, the control unit 30 determines whether the reading area is dirty (S4). If it is determined that the reading area is not dirty (S4: NO), the read data is stored in the RAM 38 as the shading correction data S (S5).

  On the other hand, when the control unit 30 determines that the reading area is dirty (S4: YES), the control unit 30 adds 1 to the number of rotations k (S6). It is determined whether or not the number of rotations k plus 1 exceeds the upper limit number of rotations k1, for example, 3 or less (S7). When the rotation number k does not exceed the upper limit rotation number k1 (S7: NO), the shading roller drive motor 31 is driven to rotate the shading roller 10 by a predetermined angle, for example, 90 degrees (S8). In this way, after the reading area on the outer peripheral surface of the shading roller 10 is made different from the reading area read in S3, the back surface reading unit 3 reads the image of the reading area on the outer peripheral surface of the shading roller 10 to obtain different read data. Obtain (S3), and perform processing operations after S4.

  On the other hand, when the number of rotations k exceeds the upper limit number of rotations k1 (S7: YES), appropriate shading correction data S for performing good image reading cannot be obtained from any of the k1 (predetermined number) reading regions. Information indicating that it is determined that the predetermined number of reading areas are dirty is notified. For example, a message that prompts the outer peripheral surface of the shading roller to be cleaned is displayed on the liquid crystal display panel 45 of the notification unit 36 (S9). At the same time, it is preferable to make a notification by turning on the LED lamp 46 for warning, or by making a warning sound by the speaker 47.

  As described above, in the copy / facsimile multifunction peripheral 100, when it is determined that the reading area on the outer peripheral surface of the shading roller 10 is contaminated, after the shading roller 10 is rotated by a predetermined angle, the reading area is different from the reading area. The back side reading unit 3 is caused to read the image and the read data is acquired. For this reason, for example, even when the first read area is dirty, it is possible to obtain read data from the read area that is determined to be free of dirt. Appropriate shading correction data S can be acquired. Further, the back side reading unit 3 can read different white reference images by rotating the shading roller 10 without adding or changing the mechanical configuration. In addition, it is possible to acquire appropriate shading correction data S for performing good image reading from a reading area in which it is determined that there is no dirt in the reading area. On the other hand, when it is determined that any of the k1 reading areas on the outer peripheral surface of the shading roller 10 is contaminated and it is determined that appropriate shading correction data S for performing good image reading cannot be acquired, the notification unit 36. This can prompt the user to clean the shading roller 10.

  In the copy / facsimile multifunction peripheral 100 shown in the present embodiment, the back surface reading unit 3 reads the image of the reading area consisting of one line on the outer peripheral surface of the shading roller 10 and acquires the read data. However, the present invention is not limited to this, and may be a reading area corresponding to a plurality of main scanning lines on the outer peripheral surface of the shading roller 10. In this case, the shading roller 10 may be stopped and the image of the reading area may be read simultaneously with a plurality of main scanning lines, or a plurality of images of the reading area may be read for each main scanning line while the shading roller 10 is rotated. Good. The reading area corresponding to the plurality of main scanning lines is preferably an area corresponding to 2 to several tens or less main scanning lines, more preferably an area corresponding to 2 to 10 or less main scanning lines. Further, the reading area corresponding to a plurality of main scanning lines is defined by an angle between the boundary of the reading area and the rotation center axis of the shading roller 10 being preferably 10 degrees or less, more preferably 5 degrees or less. It is also an area. Further, the plurality of main scanning lines may be main scanning lines that are adjacently located continuously or may be main scanning lines that are discretely positioned. Further, when the back surface reading unit 3 reads the reading region corresponding to the plurality of main scanning lines on the outer peripheral surface of the shading roller 10, the control unit 30 may determine whether or not all the reading regions are dirty, It may be determined whether or not the area is smudged with respect to at least one main scanning line in the reading area. The configuration of the copy / facsimile multifunction peripheral 100 shown in the present embodiment is only one aspect of the image reading apparatus according to the present invention, and it is needless to say that the design can be changed as appropriate without departing from the gist of the present invention. For example, it can be realized as a single machine such as a copier, a facsimile machine, or a scanner.

  The image reading apparatus according to the present invention can be used as a scanner, a facsimile machine, a copier, and a complex machine of these having a shading roller for performing shading correction on image data of a document.

1 is a cross-sectional view showing a schematic configuration of an upper part of a copy / facsimile multifunction peripheral 100 according to an embodiment of the present invention. It is explanatory drawing which shows the periphery of the reading position P2, (a) shows the case where a document is conveyed in the reading position P2, (b) shows the case where there is no document in the reading position P2. 2 is a block diagram illustrating an electrical configuration of the copy / facsimile multifunction peripheral 100. FIG. 4 is a flowchart showing processing operations of the copy / facsimile multifunction peripheral 100 based on a shading correction data acquisition program 50. 10 is a cross-sectional view showing a schematic configuration of an upper part of a conventional copy / facsimile multifunction peripheral 900. FIG.

Explanation of symbols

3 Back side reading unit (image reading means)
5 Document transport path 10 Shading roller 30 Control unit (control means, determination means, shading correction means)
33 Image processing unit (shading correction means)
36 Notification part (notification means)
38 RAM (memory)
48 Shading correction program (shading correction means)
49 Dirt judgment program (judgment means)
50 Shading correction data acquisition program (control means)
100 Copy / facsimile multifunction peripherals (image readers)
k1 Maximum number of rotations (predetermined number)
P threshold (predetermined value)
S Shading correction data

Claims (3)

An image reading unit that reads image data of a document conveyed along the document conveyance path for each main scanning line, and the image reading unit is a shading roller that is rotatably disposed at a position facing the document conveyance path. A shading correction unit that reads the image of the outer peripheral surface of the shading roller and performs shading correction on the original image data read based on the shading correction data stored in the memory. In the reading device,
Judging means for judging the presence or absence of dirt in the reading area based on reading data obtained by reading the image of the reading area corresponding to one or a plurality of main scanning lines on the outer peripheral surface of the shading roller; When the determination unit determines that the reading area is not dirty, the reading data of the reading area is stored in the memory as the shading correction data, and the determination unit determines that the reading area is dirty. And a control unit that rotates the shading roller by a predetermined angle to cause the image reading unit to read an image in a reading area different from the reading area, thereby acquiring read data. apparatus.   2. The determination unit according to claim 1, wherein the determination unit determines whether the reading area is dirty based on whether a maximum deviation between adjacent pixel data of the reading data exceeds a predetermined value. Image reading device.   3. The image reading apparatus according to claim 1, further comprising a notifying unit that notifies that when the determination unit determines that the predetermined number of reading areas are dirty. 4.

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