JP2005033457A - Image reader, image read method, and storage method for shading data - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an image reader capable of obtaining excellent shading data even without a reference member for reading the shading data such as a white reference board. <P>SOLUTION: The image reader includes an original tray 11 for feeding originals from an original bundle and a carrying path used to carry the originals fed from the original tray 11, uses a scanner 70 to read the image of a first side of the originals fed from one side of the carrying path, and uses a CIS 50 to read the image of a second side of the originals supplied from the other side of the carrying path. Then a processing apparatus 80 reads a reflected light from the white reference member by the scanner 70 and makes the reflected light shading data of the scanner 70, stores a plurality of shading data for the CIS 50 to a memory in advance, and read prescribed shading data among the plurality of the shading data stored in this memory and makes the read shading data the shading data of the CIS 50. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to an image reading apparatus that reads an image on a document, and more particularly to an image reading apparatus that rewrites shading data.
[0002]
[Prior art]
2. Description of the Related Art Conventionally, an image reading device (automatic double-sided reading device) that automatically reads image information on both sides of a document without user intervention is used as a reading device such as a copying machine or a facsimile, or a scanner for computer input. . As these automatic double-sided reading devices, a method of reading a document by reversing the front and back with a document reversing unit is most widely adopted. When inputting image information with the front and back reversed, after reading the front image with a specific document reading unit, this document is reversed and transported to the specific document reading unit again, and the back image is read. It is done. However, this automatic double-sided scanning by reversing the front and back requires that the original is once discharged and then reversed and transported again to the original scanning unit. It will be inferior. Therefore, a so-called double-sided simultaneous reading technique in which two image reading devices are provided on both the front and back sides of a document path for transporting a document and the front and back surfaces of the document are automatically read by one document transport is being studied.
[0003]
As a prior art employing such double-sided simultaneous reading, for example, in order to prevent deviation between densities when reading by two image reading devices, by arranging a white reference plate and performing shading correction, There is a technique for correcting a density difference by eliminating variations in white level between the front surface and the back surface (see, for example, Patent Document 1). In addition, for example, there is a technique for detecting sensitivity information for each channel in order to easily correct sensitivity variations between chips of an image sensor having a plurality of sensor chips (see, for example, Patent Document 2).
[0004]
[Patent Document 1]
Japanese Patent No. 2622039 (page 2-3, FIG. 1)
[Patent Document 2]
JP 2002-84403 A (page 3-4, FIG. 1)
[0005]
[Problems to be solved by the invention]
Here, when reading a document, for example, a method of irradiating light with a fluorescent lamp as a light source and reading the reflected light with an optical sensor via a reduction optical system is widely adopted. For example, a one-dimensional CCD (Charge Coupled Device) sensor is used as an optical sensor in such a system, and reading is performed in line units. However, in such a reading method, reflected light is read through a reduction optical system using several mirrors, and the entire unit tends to be large. In particular, it is difficult to dispose a plurality of image reading units having a reduction optical system so as to face each other on the document conveyance path due to space problems. Therefore, in order to solve such a space problem, for example, a light emitting diode (LED) is used as a light source, and a contact image sensor (CIS) that directly reads an image with a linear sensor via a selfoc lens, for example, It has been studied to use a so-called contact image sensor.
[0006]
As described above, when reading images on both the front and back surfaces using a reading unit using a reduction optical system, a reading unit using CIS, or the like, for example, as described in Patent Document 1, the density difference between the plurality of reading units is calculated. It is necessary to correct. In order to correct this density difference, for example, it is preferable to perform shading correction every time an image is read. In particular, in recent years, higher image quality and higher resolution of reading have progressed, and finer density correction is required. If shading correction is performed before each reading, image data with a more stable density can be obtained. It becomes possible.
[0007]
However, when the shading correction is performed every time the image is read, for example, if dust adheres to the white reference plate, a streak is generated due to the dust. In particular, when double-sided simultaneous reading is adopted and image reading means is arranged on one side and the other side on the document conveyance path, any white reference plate (white reference plate used in each image reading means) ), The document is conveyed and dust or the like easily adheres to the white reference plate.
[0008]
In addition, for example, a method of obtaining shading data at the time of product shipment and performing shading correction using the held shading data is also effective. However, for example, in CIS, when unevenness in the amount of light of a light source (LED) due to continuous lighting occurs as a change with time, streaking of image data is generated simply by holding and using shading data. Conventionally, such a streak has seldom become a problem, but the demand for improvement has become stronger with the recent increase in resolution and image quality.
[0009]
The present invention has been made in order to solve the technical problems as described above, and the object of the present invention is even when there is no reference member for reading shading data such as a white reference plate. It is to obtain good shading data.
Another object is to enable good reading even when a change in the amount of light with time occurs when a reading means using LEDs is used.
Still another object is to obtain read image data in which streaks and unevenness are suppressed in the simultaneous double-side reading of reading both front and back image data from both sides of the document conveyance path.
[0010]
[Means for Solving the Problems]
For this purpose, an image reading apparatus to which the present invention is applied includes a paper feeding unit that feeds a document from a document bundle, and a conveyance path that conveys the document fed by the paper feeding unit, The image on the first side of the document is read by the first reading unit from one side of the conveyance path, and the image on the second side of the document is read by the second reading unit from the other side of the conveyance path. In such a double-sided simultaneous reading apparatus, a first shading data acquisition unit and a second reading unit that read reflected light from the white reference member by the first reading unit and use the reflected light as the shading data of the first reading unit. A memory for storing a plurality of shading data in advance and a shading data of the second reading means by reading predetermined shading data from the plurality of shading data stored in the memory without using reflected light from the white reference member Second shading data acquisition means. The white reference member means a reference member for reading when performing shading correction. For example, the white reference member includes silver or the like as long as it does not depart from the spirit of the member. The same applies hereinafter.
[0011]
Here, the second reading means uses an LED as a light source, and the memory stores shading data acquired under a plurality of conditions after the LED in the second reading means is turned on. The plurality of conditions may be after a predetermined time has elapsed after the LED is turned on.
[0012]
Further, the second reading unit includes a light amount correction unit that performs light amount correction of the light source, and the second shading data acquisition unit performs predetermined shading from the memory based on the light amount correction performed by the light amount correction unit. The feature of reading data is preferable in that good shading data can be read with high reliability.
[0013]
From another point of view, the image reading apparatus to which the present invention is applied reads the image data of the first surface of the document by the first reading means, and the first reading means reads the first data of the document. When reading the image data of the surface, the image data of the second surface of the document is read by the second reading means without inverting the document. At this time, the first reading means uses a predetermined white reference member, while the second reading means does not use the white reference member, and the shading data rewriting means rewrites the shading data.
[0014]
Here, the shading data storage means for storing shading data acquired in advance by the second reading means under a plurality of conditions is further provided, and the shading data rewriting means is configured to store the shading data stored in the shading data storage means. If any one of them is read and rewritten, it is preferable in that good shading data can be acquired even in a use environment where the white reference member cannot be used. In particular, the shading data storage means stores a plurality of shading data for each elapsed time when the light source in the second reading device is turned on, and the shading data rewrite means corresponds to the lighting time of the light source in the second reading means. The predetermined shading data is read from the shading data storage means and the shading data is rewritten. Further, a light amount correcting unit that performs light amount correction of the light source in the second reading unit, and a storage unit that stores the shading data rewritten by the second reading unit in association with information on the light amount correction executed by the light amount correcting unit. It can be characterized by comprising.
[0015]
On the other hand, the image reading apparatus to which the present invention is applied is acquired under different conditions for the reading means, such as reading means for reading image data using an LED as a light source and shading data according to the passage of time when the LED is lit. Storing means for storing a plurality of shading data, shading data rewriting means for reading out predetermined shading data from the plurality of shading data stored in the storage means, and rewriting the shading data, and a light source used in the reading means And a light amount correction unit that corrects the amount of light, and the storage unit stores shading data associated with a light amount correction value by the light amount correction unit.
[0016]
From another category, the image reading method to which the present invention is applied is based on conditions when reading image data from a memory storing a plurality of shading data acquired under different lighting conditions for a light source. Reading the predetermined shading data, reading the image data using the read predetermined shading data, and reading the light amount correction value of the light source, and reading the predetermined shading data May be characterized by reading predetermined shading data from the memory based on the read light amount correction value.
[0017]
From another point of view, the shading data storage method to which the present invention is applied is a step of continuously turning on the LED light source for a predetermined time and reading by a sensor every time when the LED light source is turned on. A step of storing the plurality of shading data, and a step of storing a light amount correction value when performing light amount correction on the LED light source in association with the stored shading data.
[0018]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, the present invention will be described in detail based on embodiments shown in the accompanying drawings.
FIG. 1 is a diagram showing an image reading apparatus to which the present embodiment is applied. This image reading apparatus is roughly divided into a document feeding device 10 that sequentially conveys documents from a stacked document bundle, a scanner device 70 that reads an image by scanning, and a processing device 80 that processes a read image signal.
[0019]
The document feeder 10 includes a document tray 11 on which a bundle of documents composed of a plurality of documents is stacked, and a tray lifter 12 that raises and lowers the document tray 11 as an example of components of a paper feed unit. Further, a nudger roll 13 that conveys the original on the original tray 11 raised by the tray lifter 12, a feed roll 14 that conveys the original conveyed by the nudger roll 13 further downstream, and an original supplied by the nudger roll 13. Are provided with a retard roll 15. In the first conveyance path 31 where the original is first conveyed, a take-away roll 16 that conveys the originals that are being fed one by one to the downstream roll, and further conveys the original to the further downstream roll and creates a loop. The pre-registration roll 17 to be performed, the rotation is resumed at the timing after stopping once, the registration roll 18 for supplying the original while adjusting the registration to the original reading unit, the platen roll 19 for assisting the conveyance of the original being read, An out-roll 20 is provided for conveying the read original further downstream. The first transport path 31 includes a baffle 41 that rotates about a fulcrum according to the loop state of the document being transported. Further, between the platen roll 19 and the out-roll 20, a CIS (Contact Image Sensor) 50, which is the second reading means in the present embodiment, is provided.
[0020]
A second transport path 32 and a third transport path 33 are provided on the downstream side of the out-roll 20, a transport path switching gate 42 for switching between these transport paths, a discharge tray 40 for stacking documents that have been read, and a discharge tray A first discharge roll 21 that discharges the original document 40 is provided. In addition, an inverter roll 22 and an inverter pinch roll 23 that are provided in the fourth transport path 34 and the fourth transport path 34 for switching back the document that has passed through the third transport path 33 and actually switch back the document, The document switched back by the fourth transport path 34 is again guided to the first transport path 31 including the pre-registration roll 17 and the like, and the document switched back by the fourth transport path 34 is discharged to the discharge tray 40. The transport paths of the second discharge roll 24, the fifth transport path 35, and the sixth transport path 36 that are provided in the sixth transport path 36 and the sixth transport path 36 and transport the inverted document to the first discharge roll 21. An exit switching gate 43 for switching is provided.
[0021]
The nudger roll 13 is lifted up and held at the retracted position during standby, and descends to a nip position (original conveyance position) during conveyance of a document to convey the uppermost document on the document tray 11. The nudger roll 13 and the feed roll 14 convey a document by connecting a feed clutch (not shown). The pre-registration roll 17 makes a loop by abutting the leading end of the document against the stopped registration roll 18. In the registration roll 18, when the loop is created, the leading edge of the document bitten by the registration roll 18 is returned to the nip position. When this loop is formed, the baffle 41 opens around the fulcrum and functions so as not to disturb the document loop. Further, the take away roll 16 and the pre-registration roll 17 hold a loop during reading. By this loop formation, the read timing can be adjusted, and the skew associated with the document conveyance at the time of reading can be suppressed, and the alignment adjustment function can be enhanced. In accordance with the reading start timing, the stopped registration roll 18 starts rotating, and is pressed against the second platen glass 72B (described later) by the platen roll 19 to form a CCD image sensor (first reading means). The image data is read from the bottom surface direction as described later.
[0022]
The conveyance path switching gate 42 switches so that the document passing through the out-roll 20 is guided to the second conveyance path 32 and discharged to the discharge tray 40 at the end of reading one-sided document and at the same time when reading both-side documents simultaneously. It is done. On the other hand, the transport path switching gate 42 is switched so as to guide the document to the third transport path 33 in order to invert the document when the double-sided document is sequentially read. The inverter pinch roll 23 is retracted with the feed clutch (not shown) turned off when the double-sided original is sequentially read, and the nip is released, leading the original to the inverter path (fourth conveyance path 34). Thereafter, the inverter pinch roll 23 is nipped, the original to be inverted by the inverter roll 22 is guided to the pre-registration roll 17, and the original to be reversed is conveyed to the second discharge roll 24 in the sixth conveyance path 36.
[0023]
The scanner device 70 is configured to be capable of placing the document feeder 10 described above, supports the document feeder 10 by an apparatus frame 71, and reads an image of the document conveyed by the document feeder 10. Yes. The scanner device 70 includes a first platen glass 72A for placing a document to be read in a stationary state on a device frame 71 forming a casing, and a light for reading a document being conveyed by the document feeder 10. A second platen glass 72 </ b> B is formed to form the opening.
[0024]
The scanner device 70 is stationary under the second platen glass 72B and scans the entire first platen glass 72A to read an image, and the light obtained from the full rate carriage 73 is image-coupled. A half-rate carriage 75 is provided to provide a portion. The full-rate carriage 73 includes an illumination lamp 74 that irradiates light on the original and a first mirror 76A that receives reflected light obtained from the original. Further, the half-rate carriage 75 is provided with a second mirror 76B and a third mirror 76C that provide the light obtained from the first mirror 76A to the imaging unit. Further, the scanner device 70 includes an imaging lens 77 that optically reduces the optical image obtained from the third mirror 76C, and a CCD (Charge Coupled Device) that photoelectrically converts the optical image formed by the imaging lens 77. ) An image sensor 78 and a drive substrate 79 provided with the CCD image sensor 78 are provided, and an image signal obtained by the CCD image sensor 78 is sent to the processing device 80 via the drive substrate 79.
[0025]
Here, first, when reading an image of a document placed on the first platen glass 72A, the full rate carriage 73 and the half rate carriage 75 move in the scanning direction (arrow direction) at a ratio of 2: 1. . At this time, the light of the illumination lamp 74 of the full rate carriage 73 is irradiated on the surface to be read of the document, and the reflected light from the document is reflected in the order of the first mirror 76A, the second mirror 76B, and the third mirror 76C. Then, it is guided to the imaging lens 77. The light guided to the imaging lens 77 forms an image on the light receiving surface of the CCD image sensor 78. The CCD image sensor 78 is a one-dimensional sensor and processes one line at the same time. When reading of one line in this line direction (main scanning direction of scanning) is completed, the full-rate carriage 73 is moved in a direction (sub-scanning direction) orthogonal to the main scanning direction to read the next line of the document. By executing this over the entire document size, reading of one page of the document is completed.
[0026]
On the other hand, the second platen glass 72B is constituted by a transparent glass plate having a long plate-like structure, for example. A document conveyed by the document feeder 10 passes over the second platen glass 72B. At this time, the full-rate carriage 73 and the half-rate carriage 75 are stopped at the solid line positions shown in FIG. First, the reflected light of the first line of the document that has passed through the platen roll 19 of the document feeder 10 is imaged by the imaging lens 77 via the first mirror 76A, the second mirror 76B, and the third mirror 76C. An image is read by the CCD image sensor 78 which is the first sensor in the present embodiment. That is, after one line in the main scanning direction is simultaneously processed by the CCD image sensor 78 which is a one-dimensional sensor, the next line in the main scanning direction of the original conveyed by the original feeding device 10 is read. After the leading edge of the document reaches the reading position of the second platen glass 72B, the document passes through the reading position of the second platen glass 72B, whereby reading of one page is completed in the sub-scanning direction.
[0027]
In the present embodiment, the full-rate carriage 73 and the half-rate carriage 75 are stopped, and the first platen glass 72B is used to read the first surface of the document by the CCD image sensor 78. The second side of the document can be read by the CIS 50 serving as the second sensor when the same document is conveyed instead of coincidence. That is, by using the CCD image sensor 78 as the first sensor and the CIS 50 as the second sensor, it is possible to simultaneously read the images on both the front and back sides of the original by conveying the original to the conveyance path once. Yes.
[0028]
FIG. 2 is a diagram for explaining a reading structure using the CIS 50. As shown in FIG. 2, the CIS 50 is provided between the platen roll 19 and the out roll 20. One side (first side, front side) of the original is pressed against the second platen glass 72B, and the image on the first side is read by the CCD image sensor 78. On the other hand, in the CIS 50, an image on one side (second side, back side) is read from the other side facing through a conveyance path for conveying a document. The CIS 50 includes a glass 51, an LED (Light Emitting Diode) 52 that irradiates light onto the second surface of the document through the glass 51, and a SELFOC lens that is a lens array that condenses the reflected light from the LED 52. 53 and a line sensor 54 which is an image sensor for reading the light collected by the Selfoc lens 53. As the line sensor 54, a CCD, a CMOS sensor, a contact sensor, or the like can be used, and an image having an actual width (for example, A4 longitudinal width 297 mm) can be read. In the CIS 50, since the image is captured using the SELFOC lens 53 and the line sensor 54 without using the reduction optical system, the structure can be simplified, the housing can be downsized, and the power consumption can be reduced. Can be reduced. When reading a color image, combining the LED 52 with LED light sources of three colors R (red), G (green), and B (blue), and using a set of three columns for RGB three colors as the line sensor 54. good. Similar to the reading of the image on the first surface, one line in the main scanning direction is simultaneously processed by the one-dimensional line sensor 54, and then the next line in the main scanning direction in the conveyed document is read. In this way, one page of the back side of the conveyed document is read in the sub-scanning direction.
[0029]
Further, when the image is read by the CIS 50, a control member 55 extending from the casing of the CIS 50 and an abutting member 60 for abutting the sheet pressed by the control member 55 are provided on the conveyance path constituting the reading unit. A guide member 61 is provided on the downstream side of the abutting member 60. The control member 55 and the abutting member 60 are positioned in the conveyance path from the front surface to the rear surface of the document feeder 10 in a direction orthogonal to the document conveyance path (that is, from the front surface to the rear surface of the document feeder device 10). Correspondingly provided.
[0030]
Further, since the CIS 50 employs the SELFOC lens 53 as an optical imaging lens, the depth of focus (field of view) is as shallow as about ± 0.3 mm, which is about 1 compared with the case where the scanner device 70 is used. / 13 or less depth. When reading with the CIS 50, it is required to set the reading position of the document within a predetermined narrow range. Therefore, in the present embodiment, the control member 55 is provided, and the document is pressed against the abutting member 60 by the control member 55 and conveyed, so that the posture of the document between the platen roll 19 and the out-roll 20 can be stabilized. It was configured to be controllable. 2 indicates the movement of the paper when the control member 55 is provided. It can be understood that the transported paper is transported while the document is pressed against the abutting member 60. That is, by reading the document conveyed by the control member 55 while being pressed against the abutting member 60, the sweetness of the focus when the CIS 50 having a shallow depth of field is used is improved.
[0031]
Next, the processing device 80 shown in FIG. 1 will be described.
FIG. 3 is a block diagram for explaining the processing device 80. The processing device 80 to which the present embodiment is applied is large, and includes a signal processing unit 81 that processes image information obtained from sensors (CCD image sensor 78 and line sensor 54), a document feeder 10 and a scanner device 70. And a control unit 90 for controlling. The signal processing unit 81 performs predetermined image processing on outputs from the CCD image sensor 78 that reads the front surface (first surface) and the line sensor 54 of the CIS 50 that reads the back surface (second surface). The signal processing unit 81 includes an AFE (Analog Front End) 82 that performs analog signal processing on the output from the line sensor 54, and an ADC (Analog to Digital Converter) 83 that converts the analog signal into a digital signal. Yes. However, these functions may be configured to be processed inside the CIS 50. The signal processing unit 81 includes two image processing circuits that perform various processes such as shading correction and offset correction on the digital signal, and performs image processing on the image data on the front surface (first surface). A first image processing circuit 100 for performing image processing, and a second image processing circuit 200 for performing image processing on image data on the back surface (second surface). Outputs from these image processing circuits are output to a host system such as an IOT (Image Output Terminal) such as a printer or a personal computer (PC).
[0032]
On the other hand, the control unit 90 includes an image reading control 91 that controls the entire document feeder 10 and the scanner device 70, including various double-sided scanning control and single-sided scanning control, a CCD / image sensor 78 and a CCD / CIS 50 that controls the CIS 50. The CIS control 92, the lamp control 93 for controlling the LED 52 of the CIS 50 and the illumination lamp 74 of the full-rate carriage 73 in accordance with the reading timing, the on / off of the motor in the scanner device 70, etc. are performed to scan the full-rate carriage 73 and the half-rate carriage 75. A scan control 94 for controlling the operation, a motor control in the document feeder 10, a transport mechanism control 95 for controlling various roll operations, feed clutch operations, gate switching operations, and the like are provided. . From these various controls, control signals are output to the document feeder 10 and the scanner device 70, and these operations can be controlled based on the control signals. The image reading control 91 sets a reading mode based on a control signal from the host system, a sensor output detected in the automatic selection reading function, a selection from the user, and the like, and controls the document feeder 10 and the scanner device 70. I have control. As the reading mode, the double-sided simultaneous reading mode by one pass (without reversal), the reversing double-sided reading mode by reversing pass, the single-sided reading mode by one pass, etc. can be considered.
[0033]
Next, the function and operation of each image processing circuit (the first image processing circuit 100 and the second image processing circuit 200) will be described.
FIG. 4 is a block diagram illustrating the configuration of the signal processing unit 81 in further detail. The first image processing circuit 100 includes a first CPU 101 that performs overall control, an AFE 102 that performs sample hold, offset adjustment, A / D conversion, and the like on the surface image data output from the CCD image sensor 78, and front and back images. A selector (SEL) 103 for selecting and outputting data is provided. Further, an A integrated circuit (ASIC-A) 110 that performs shading correction, line interpolation (RGB misregistration interpolation), and the like, and an B integrated circuit (ASIC-B) that performs MTF filter, reduction / enlargement processing, binarization processing, etc. ) 130.
[0034]
On the other hand, the second image processing circuit 200 is obtained from a second CPU 201 that performs overall control, for example, white reference shading data at the time of factory shipment, a flash ROM (FROM) 202 that stores (stores) LED light amount correction values, and a CIS 50. A C integrated circuit (ASIC-C) 210 that performs various image processing on the backside image data, and temporarily holds the backside image data that has been subjected to image processing, and outputs it to the selector 103 in accordance with a predetermined output timing. The memory 203 is provided. In the present embodiment, white reference shading data obtained in advance at the time of factory shipment is stored in a flash ROM (FROM) 202 by the CIS 50 which is a contact image sensor for reading the back surface.
[0035]
FIG. 5 is a block diagram showing the configuration of the A integrated circuit (ASIC-A) 110. The A integrated circuit 110 includes a shading correction unit 111 for correcting shading data in the CCD image sensor 78, a GAP correction unit 112 for correcting the positions of RGB line sensors, a black line correction unit 113 for correcting black lines, and an input. ENL115 for side tone correction, BGR → L ^* , A ^* , B ^* A color space conversion 116 for converting to a color space is provided. In addition, a timing generation unit 119 that generates drive clocks for the CCD image sensor 78 and the AFE 102, and a CPU interface 120 that communicates with the first CPU 101 are provided.
[0036]
FIG. 6 is a block diagram showing the configuration of the B integrated circuit (ASIC-B) 130. The B integrated circuit 130 includes a digital filter unit 131 that performs MTF correction and smoothing, a sub-scanning reduction unit 132 that performs a reduction process with respect to the sub-scanning direction that is the document transport direction, and a CCD that is in a direction orthogonal to the document transport direction. A main scanning enlargement / reduction unit 133 that performs enlargement / reduction processing in the main scanning direction, which is the scanning direction of the image sensor 78, a background removal unit 135 that removes the background of the read document, L ^* , A ^* , B ^* → A lookup table (LUT) 136 for color space conversion to Y, M, C, and K is provided. Further, a background detection unit 139 that detects the background of the read document and a CPU interface 140 that communicates with the first CPU 101 are provided.
[0037]
FIG. 7 is a block diagram showing the configuration of the C integrated circuit (ASIC-C) 210. The C integrated circuit 210 includes a multiplex (MPX) circuit 211 that synthesizes output signals of two channels consisting of Odd / Evn, a shading correction unit 212 that performs shading correction based on data stored in the shading memory 221, and an input floor. L to execute adjustment correction ^* A conversion (LUT) unit 213, a sub-scanning / reduction unit 214 that performs a reduction process in the sub-scanning direction, a main-scan enlargement / reduction unit 215 that performs an enlargement / reduction process in the main-scanning direction, a filter unit 216 that performs MTF correction and smoothing, A background removal unit 217 that performs background removal based on a background detection result by the background detection unit 222, and a look-up table (LUT) 218 that performs output tone correction, and an error diffusion processing unit 219 that performs binarization are provided. In addition, a CPU interface 223 that performs communication with the second CPU 201 is provided.
[0038]
FIGS. 8A and 8B are diagrams showing examples of data stored in the flash ROM (FROM) 202. FIG. In FIG. 8A, a plurality of types of shading data for one line are stored. In FIG. 8B, an LED light amount correction value for correcting the output to a constant value is stored. For example, the data shown in FIG. 8B can be stored in a non-volatile memory (NVM) or the like different from the flash ROM (FROM) 202. The shading data for one line shown in FIG. 8A is data acquired by using a CIS50 that is a contact image sensor for reading the back surface under predetermined conditions at the time of factory shipment, for example, 7100. One line of data of pixels × 8 bits is stored in, for example, an 8 Kbyte area. The predetermined condition is, for example, a time immediately after the LED 52 is lit, 2 minutes, 5 minutes, or the like, and when these times have elapsed, a predetermined white reference plate provided at the time of factory shipment is read. Shading data is stored. Further, the LED light amount correction value stored in FIG. 8B is necessary for setting the output to a predetermined value (for example, a value of 200 when the image density is expressed by 0-255). Current setting value. The LED light amount correction value at the time when the shading data shown in FIG. 8A is acquired is stored. In the CIS 50, for example, about 200 LEDs 52 are provided in one line.
[0039]
Here, the characteristics of the LED 52 mounted on the CIS 50 tend to be as shown in FIG. FIG. 9 is a diagram showing the characteristics of the light quantity change of the LED 52 over time. The horizontal axis indicates time, and the vertical axis indicates the light intensity level. Here, the LED current is kept constant. As shown in FIG. 9, the light quantity of the LED 52 gradually decreases as the temperature rises for a predetermined period after lighting. As a result, for example, the LED light amount correction value for maintaining the light amount of 100% differs between immediately after the LED 52 is turned on (time 0 minutes) and after a certain time has elapsed. In the present embodiment, for example, at the time of shipment from the factory, a plurality of shading data is sampled every predetermined time after the LED 52 is turned on, and the shading data obtained by the sampling is stored in a flash ROM (FROM) 202. . Further, the light amount correction value as shown in FIG. 9 at this time is stored in the flash ROM (FROM) 202 or the like in association with the shading data acquisition.
[0040]
The characteristics of the LED 52 are different for each model. The value of the LED light amount correction value as shown in FIG. Based on the LED light amount correction value 0 (80h), the LED light amount correction value 2 (86h), and the LED light amount correction value 5 (8Dh) A coefficient is determined. The coefficient to be determined is, for example, 1.025 (2.5%), 1.075 (7.5%), or the like. For example, when the light amount correction of less than 2.5% (1.025) is performed from the LED light amount correction value 0, which is the initial value of the light amount correction, by these coefficients, the shading data 0 shown in FIG. When the LED light amount correction value 0 to 2.5% (1.025) or more and less than 7.5% (1.075) is selected, the shading data 2 is selected and the LED light amount correction value is selected. When the light amount correction from 0 to 7.5% (1.075) or more is performed, the shading data rewriting process such as selecting the shading data 5 is executed.
[0041]
Next, a shading data storage method and an image reading method according to the present embodiment will be described with reference to flowcharts.
FIG. 10 is a flowchart showing a process for collecting and storing shading data, for example, at the time of factory shipment. When collecting shading data, first, the power of the CIS 50 is turned on (step 301). The second image processing circuit 200 acquires true black data when the LED 52 of the CIS 50 is turned off and stores it in a memory (a predetermined working memory or the like), and then subtracts this value from the read data. , CIS black correction is performed (step 302). Here, first, counting is started with “i = 0” (step 303), and lighting of the LED 52 is started (step 304).
[0042]
Then, weighting is performed such that “i = 0” is 0 minutes, “i = 1” is 2 minutes, and “i = 2” is 5 minutes (step 305), and the light quantity correction of the LED 52 is performed (step 305). 306). As the light amount correction, for example, there is a method of reading the reflected light from the white reference plate with the line sensor 54 in a state where the LED 52 is turned on, and correcting based on the read value. Then, the light amount correction result is written in a memory such as a flash ROM (FROM) 202 as an LED light amount correction value (step 307). Further, the shading data at this time is collected (step 308), white variation correction data is collected and written in a memory such as a flash ROM (FROM) 202 (step 309). Thereafter, the counter “i” is incremented to “i = i + 1” (step 310). For example, when collecting data for up to 5 minutes with “i = 2”, it is determined in step 311 whether “i” is smaller than 2. If it is less than 2, the process returns to step 305 and the process is repeated. When “i” becomes 2 or more, the power of the CIS 50 is turned off (step 312), and the shading data collection is finished (step 313).
[0043]
FIG. 11 is a flowchart showing shading correction processing when reading is actually executed by the document feeder 10. It is detected by a sensor (not shown) that the user has placed a document on the document tray 11 (step 401), and the power of the CIS 50 is turned on based on an instruction from the CCD / CIS control 92 of the processing device 80 (step 401). Step 402). In the second image processing circuit 200, black correction in the CIS 50 is executed (step 403), and light amount correction of the LED 52 is executed (step 404). This light quantity correction value is stored in a predetermined memory (not shown) provided in the CIS 50, for example. The second CPU 201 reads the LED light amount correction value stored in the memory (step 405), stores it in a working memory (not shown) provided in the second CPU 201, for example, and executes the subsequent processing. .
[0044]
In step 406, predetermined shading data is acquired based on “how much LED light amount correction has been performed with respect to the LED light amount correction initial value”. As a premise thereof, it is assumed that the coefficients 1.025 and 1.075 are obtained based on the LED light quantity correction value shown in FIG. When the executed light amount correction is less than 2.5% (1.025) of the LED light amount correction value 0 which is the initial value of light amount correction, the shading data 0 shown in FIG. 8A is selected. Further, when the executed light amount correction is from the LED light amount correction value 0 to 2.5% (1.025) or more and less than 7.5% (1.075), the shading data 2 is selected. When the LED light amount correction value is 0 to 7.5% (1.075) or more, the shading data 5 is selected. In this way, predetermined shading data is selected from a plurality of shading data as shown in FIG. 8A stored in the flash ROM (FROM) 202.
[0045]
The second CPU 201 writes the selected shading data into the shading memory 221 in the C integrated circuit (ASIC-C) 210 (step 407). Thereafter, scanning is started, and image data is read (scanned) (step 408). After this reading is completed, the power of the CIS 50 is turned off (step 409), and a series of image data reading processing is completed (step 410).
[0046]
In the processing shown in FIGS. 10 and 11, the predetermined shading data is read from the flash ROM (FROM) 202 based on the LED light amount correction value. However, the method of reading the shading data is not limited to this. It is not something that can be done. For example, if the continuous lighting time of the LED 52 can be grasped at the time of reading an image, it can be read based on the grasped lighting time. Further, even when the continuous lighting is not performed, for example, the rising temperature of the LED 52 is grasped based on the number of prints, the environmental temperature, and the like, and the optimum shading data is selected based on the grasped rising temperature. You can also.
[0047]
As described above in detail, in the present embodiment, a plurality of shading data is stored every time when the LED 52 is turned on at the time of shipment. Further, when reading an image, the shading data is rewritten and used based on a predetermined condition. As a result, in the CIS 50 as the second reading means for reading the second side (back side) of the original, even when there is no white reference member such as a white reference plate or a white reference roll, appropriate shading correction is executed. can do. In particular, when the CIS 50 is used, the LED 52 whose light amount greatly varies with the passage of time is used. However, even when the LED 52 is used as a light source, good shading data can be rewritten.
[0048]
Furthermore, when performing double-sided simultaneous reading as in the present embodiment, if a white reference plate to be read by the CIS 50 is provided on the document conveyance path, the document is conveyed while rubbing the white reference plate. Become. In such a case, for example, carbon stains of a pencil easily adhere to the white reference plate, which becomes dust and adversely affects acquisition of correct shading data. However, according to the present embodiment, the preferred shading data is rewritten and used based on the data stored in the flash ROM (FROM) 202, thereby avoiding the influence of such dust and the like and suppressing the streaks and unevenness. An image can be obtained.
[0049]
【The invention's effect】
As described above, according to the present invention, even when there is no reference member for reading shading data such as a white reference plate, good shading data can be obtained.
[Brief description of the drawings]
FIG. 1 is a diagram illustrating an image reading apparatus to which the exemplary embodiment is applied.
FIG. 2 is a diagram for explaining a reading structure using CIS.
FIG. 3 is a block diagram for explaining a processing apparatus;
FIG. 4 is a block diagram detailing a configuration of a signal processing unit.
FIG. 5 is a block diagram showing a configuration of an A integrated circuit (ASIC-A).
FIG. 6 is a block diagram showing a configuration of a B integrated circuit (ASIC-B).
FIG. 7 is a block diagram showing a configuration of a C integrated circuit (ASIC-C).
FIGS. 8A and 8B are diagrams showing examples of data stored in a flash ROM (FROM). FIGS.
FIG. 9 is a diagram showing characteristics of changes in the amount of light of an LED over time.
FIG. 10 is a flowchart showing a process for collecting and storing shading data at the time of factory shipment, for example.
FIG. 11 is a flowchart showing shading correction processing when reading is actually executed by the document feeder.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 10 ... Document feeder, 11 ... Document tray, 13 ... Nudger roll, 19 ... Platen roll, 31 ... 1st conveyance path, 50 ... CIS (Contact Image Sensor), 52 ... LED, 54 ... Line sensor, 60 ... Thing Abutting member, 70 ... scanner device, 72B ... second platen glass, 78 ... CCD (Charge Coupled Device) image sensor, 80 ... processing device, 81 ... signal processing unit, 90 ... control unit, 100 ... first image processing circuit, DESCRIPTION OF SYMBOLS 101 ... 1st CPU, 110 ... A integrated circuit (ASIC-A), 130 ... B integrated circuit (ASIC-B), 200 ... 2nd image processing circuit, 201 ... 2nd CPU, 202 ... Flash ROM (FROM), 210 ... C integrated circuit (ASIC-C), 212 ... shading correction unit, 221 ... shading memory

Claims (16)

A paper feeder that feeds documents from a bundle of documents;
A conveyance path for conveying the document fed by the sheet feeding unit;
First reading means for reading an image of the first surface of the document from one side of the conveyance path;
Second reading means for reading an image of the second surface of the document from the other side of the transport path;
First shading data acquisition means for reading reflected light from the white reference member by the first reading means and using it as the shading data of the first reading means;
A memory for storing in advance a plurality of shading data for the second reading means;
Second shading data acquisition means for reading predetermined shading data from a plurality of shading data stored in the memory and using the reflected light from the white reference member as the shading data of the second reading means; An image reading apparatus. The second reading means uses an LED as a light source,
The image reading apparatus according to claim 1, wherein the memory stores shading data acquired under a plurality of conditions after the LED in the second reading unit is turned on. The image reading apparatus according to claim 2, wherein the memory stores a plurality of shading data read after a predetermined time has elapsed after the LED is turned on. A light amount correction unit for performing light amount correction of the light source in the second reading unit;
The image reading apparatus according to claim 1, wherein the second shading data acquisition unit reads predetermined shading data from the memory based on the light amount correction performed by the light amount correction unit. First reading means for reading image data of the first side of the document;
Second reading means for reading image data on the second side of the original without inverting the original when reading image data on the first side of the original by the first reading means;
The first reading unit rewrites shading data using a predetermined white reference member, and the second reading unit includes a shading data rewriting unit that rewrites shading data without using a white reference member. Reading device. A shading data storage means for storing shading data acquired in advance by the second reading means under a plurality of conditions;
6. The image reading apparatus according to claim 5, wherein the shading data rewriting unit reads and rewrites any of the shading data stored in the shading data storage unit. The shading data storage means stores a plurality of shading data for each elapse of time when the light source in the second reading means is turned on,
7. The shading data rewriting unit reads out predetermined shading data from the shading data storage unit and rewrites shading data according to a lighting time of the light source in the second reading unit. The image reading apparatus described. A light amount correcting means for performing light amount correction of a light source in the second reading means;
6. The image reading device according to claim 5, further comprising storage means for storing the shading data rewritten by the second reading means in association with information on light quantity correction executed by the light quantity correction means. apparatus. Reading means for reading image data;
Storage means for storing a plurality of shading data acquired under different conditions for the reading means;
An image reading apparatus comprising: shading data rewriting means for reading predetermined shading data from the plurality of shading data stored in the storage means and rewriting shading data. The image reading apparatus according to claim 9, wherein the reading unit uses an LED as a light source. The image reading apparatus according to claim 10, wherein the storage unit stores shading data corresponding to a lapse of time when the LED is turned on. A light amount correcting unit for correcting the light amount of the light source used in the reading unit;
The image reading apparatus according to claim 9, wherein the storage unit stores shading data associated with a light amount correction value obtained by the light amount correction unit. Reading predetermined shading data based on conditions when reading image data from a memory storing a plurality of shading data acquired under different lighting conditions for the light source;
A method of reading image data using the read predetermined shading data. A step of reading a light amount correction value of the light source;
The image reading method according to claim 13, wherein the step of reading the predetermined shading data reads predetermined shading data from the memory based on the read light amount correction value. Turning on the LED light source continuously for a predetermined time;
Storing a plurality of shading data read by a sensor every time when the LED light source is turned on. The shading data storage method according to claim 15, further comprising a step of storing a light amount correction value when performing light amount correction on the LED light source in association with the stored shading data.

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