JP3825997B2 - Double-sided image reader - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a double-sided image reading apparatus that simultaneously reads both sides of a document.
[0002]
[Prior art]
2. Description of the Related Art Conventionally, in a double-sided image reading apparatus that reads both sides of a document with a plurality of reading means, reading means for reading the document are arranged on both sides of the document transport path to read the document.
[0003]
In the double-sided image reading apparatus, since the reading means are arranged facing each other, when both sides of the original are read simultaneously, transmitted light or show-through of the original is caused by the light source of the reading means arranged on one side of the conveyance path and reading one surface of the original. Occurs, which affects the reading data of the reading means that is arranged on the other side of the conveyance path and reads the other surface of the document.
[0004]
In view of such a problem, a technique for reducing the influence on the opposed reading means is disclosed in, for example, Japanese Patent Laid-Open No. 9-321947. In the double-sided image reading apparatus disclosed in Japanese Patent Laid-Open No. 9-321947, a reading unit having a light source for irradiating a document is arranged on one side and the other side of a conveyance path, and a light source of the reading unit that reads one surface of the document The light source of the reading means for reading the other surface is turned on and off alternately. This eliminates the influence on the read data such as transmitted light and show-through caused by the light source of the reading means arranged on the opposite side across the document.
[0005]
In the double-sided image reading apparatus disclosed in Japanese Patent Laid-Open No. 9-467485, reading means for reading a document is arranged on one surface side and the other surface side of the document, and one surface and the other surface of the document are selected by the selecting means. And read. Also, when processing the read read data, the processing parameters such as the density conversion table are changed between the read data of the one surface and the other surface, thereby absorbing the image quality difference between the one surface and the other surface. .
[0006]
[Problems to be solved by the invention]
However, in the double-sided image reading apparatus disclosed in Japanese Patent Laid-Open No. 9-321947, it is necessary to use a light source that is very quick in turning on and off. Therefore, there is a problem that the reading speed of the document is restricted by the response of the light source.
[0007]
In the double-sided image reading apparatus disclosed in Japanese Patent Application Laid-Open No. 9-46485, the same parameter is always given to the reading data of one surface and the other surface. The difference in image quality is not resolved when reading the other surface at the same time.
[0008]
An object of the present invention is to provide a double-sided image reading apparatus capable of absorbing a difference in image quality of a document read when both sides of the document are read simultaneously and when reading one side of the document.
[0009]
[Means for Solving the Problems]
  According to the present invention, reading means having a light source for exposing the original and a photoelectric conversion means for obtaining an electric signal corresponding to the amount of received light are arranged on one surface side and the other surface side of the original, respectively, and the original from each of the light sources In a double-sided image reading apparatus that reads images on both sides of the document by irradiating light on
  Input means for inputting the characteristics of the original and the reading conditions of the original;
  When the pair of reading means simultaneously reads both sides of the original with the respective light sources turned on, the reading when one of the reading means turns on one of the light sources and reads one side of the original is performed. Correction means for correcting the reading density of the reading means to be darker when reading both sides of the document with the respective light sources of the reading means turned on than the reading density of the means,
  The correction means includes
    A first correction unit that darkens a reading density of the reading unit by changing a light amount of a light source of the reading unit;
    A second correction unit that darkens the reading density of the reading unit by changing an amplification factor with respect to an analog electric signal obtained by the photoelectric conversion unit;
    Third correction means for darkening the reading density of the reading means by changing density conversion characteristics for performing density conversion processing after converting an analog electric signal obtained by the photoelectric conversion means into a digital electric signal When,
    Based on the characteristics of the document input by the input means and the reading conditions of the document, the light quantity of the light sourceIs high enoughThe first correction means for setting the light amount of the light source low is selected, and the light amount of the light source is selected.Is lowAnd the second correction means is selected when the original having a low density is read, and the light quantity of the light sourceIs lowThe double-sided image reading apparatus further includes a selection unit that selects the third correction unit when reading the original that requires halftone reproducibility.
[0010]
  According to the present invention, reading means having light sources are arranged on one surface side and the other surface side of the document, respectively, and images on both sides of the document are read by irradiating light from each light source. When the reading means arranged on one surface and the other surface side of the document reads both sides of the document at the same time with the respective light sources turned on, either one of the reading means arranged on both sides of the document conveyance path is read. The correction means corrects the reading density of each reading means to be darker than when reading one side of the document with the light source on. Therefore, it is possible to equalize the density of the scanned image when scanning both sides of the document simultaneously and when scanning one side of the document.The When scanning images on both sides of the document, the amount of light from the light source is reduced in consideration of interference from the other light source, thereby reducing the show-through that occurs when both sides are scanned simultaneously.can do. Moreover, when reading both sides simultaneously, the light source of the pair of reading means is turned on, and when reading one side, the light source of one reading means is turned off and the power saving is measured. A read image can be obtained.
  The correction means includes first to third correction means.
[0012]
  FirstWhen reading the images on both sides of the document, the correction means reduces the light intensity of the light source in consideration of interference from the other light source so that the reading density is darker than when reading the image on one side of the document.The In this state,Reading density is stabilized by reading.
[0014]
  ReadingThe capturing unit includes a photoelectric conversion unit that obtains an electrical signal corresponding to the amount of received light, thereby receiving the reflected light from the document irradiated by the light source and converting it into an analog electrical signal.SecondThe correction means applies an analog electric signal obtained by the photoelectric conversion means so that the reading density is lower when reading both sides of the document at the same time than when reading one side of the document.IncreaseChange width ratio. thisThis stabilizes the reading density.
[0016]
  ThirdThe correction means converts the analog electrical signal obtained by the photoelectric conversion means into a digital electrical signal so that when reading both sides of the document simultaneously, the reading density is darker than when reading one side of the document. Perform density conversion processing by changing density conversion characteristics. thisThis stabilizes the reading density.
  The selection means selects one of the first to third correction means based on the characteristics of the document such as designation when reading a photograph by the input means and the reading conditions such as reading the document lightly or darkly. The correction unit can perform reading suitable for the document by performing correction by any one of the first to third correction units selected by the selection unit.
[0018]
  The correction means is selected by the light quantity of the light source.Is high enoughIf this is the case, select the first correction means and the amount of light from the light source.Is lowWhen the original image with low density is read, the second correction means is selected and the light quantity of the light sourceIs lowIn addition, when reading a document image that requires halftone reproducibility, it is possible to perform reading suitable for the document by selecting and correcting the third correction means.
[0019]
DETAILED DESCRIPTION OF THE INVENTION
FIG. 1 is a schematic sectional view showing a configuration of a double-sided image reading apparatus 1 according to an embodiment of the present invention. FIG. 2 is a functional block diagram showing an electrical configuration of the double-sided image reading apparatus 1. The double-sided image reading apparatus 1 can read a document in a stationary reading mode for reading a stationary document and a traveling reading mode for reading a transported document. In the traveling reading mode, the original can be read by a single-sided reading mode for reading an image on one side of the original and a double-sided reading mode for simultaneously reading images on both sides of the original.
[0020]
The double-sided image reading apparatus 1 includes a stationary document reading unit 2 that is a portion that reads a stationary document in a stationary reading mode, a first traveling document reading unit 3 that is a portion that reads a document conveyed in a traveling reading mode, and a first traveling document reading unit 3. 2 running document reading unit 4. The stationary document reading unit 2 manually places a document that is not subject to automatic feeding, such as a book document or a pasted document, on the first contact glass 10 made of transparent glass, and reads the document in a stationary state. The first running document reading unit 3 reads one surface of a running document that is automatically fed onto the transparent glass second contact glass 11. The second traveling document reading unit 4 reads the other surface of the traveling document that is automatically fed onto the second contact glass 11.
[0021]
Image signals of documents read by the stationary document reading unit 2, the first traveling document reading unit 3, and the second traveling document reading unit 4 are sent to a first image processing unit 5 and a second image processing unit 6 described later, respectively. . The image data processed by the first image processing unit 5 and the second image processing unit 6 is stored in the image memory 13 via the image processing relay unit 12.
[0022]
The system controller 14 controls the reading control unit 16 via the communication control unit 15, and further controls the image processing relay unit 12 and the image memory 13 via the system bus 17, so that a series of operations when reading a document can be performed. The entire double-sided image reading apparatus 1 is controlled so as to be appropriately performed. The operation unit 18 is a unit for a user to give various instructions to the double-sided image reading apparatus 1 and includes operation keys. For example, when reading a document in the travel reading mode, the single-sided reading mode or the double-sided reading mode is selected. can do.
[0023]
The double-sided image reading apparatus 1 includes a main body portion 7 and an opening portion 8 which are housings. The main body 7 includes a first contact glass 10, a second contact glass 11, a document reference plate 19, and a first scanning system 20 that is a scanning unit that reads one surface of the document. The first contact glass 10 and the second contact glass 11 are juxtaposed on the upper surface of the main body portion 7. The document reference plate 19 is disposed on the upper surface of the first contact glass 10 at the end on the side where the second contact glass 11 is juxtaposed. The first reading scanning system 20 is disposed inside the main body unit 7.
[0024]
An index indicating the size and placement direction of the document is printed on the document reference plate 19. According to this index, the document can be easily placed on the stationary document reading unit 2 on the first contact glass 10. On the opposite side of the document reference plate 19 with respect to the first contact glass 10, the first photoelectric conversion element 21 of the first reading scanning system 20 to be described later is used for carrying out seeding, that is, determining the white level. A one-reference white plate 22 is provided.
[0025]
The first reading scanning system 20 disposed inside the main body 7 includes a first scanning unit 25, a second mirror 26, and a third mirror that integrally support a first light source 23 and a first mirror 24 that irradiate a document. 27, a second scanning unit 28 that integrally supports the first imaging lens 29, and a first photoelectric conversion element 21. The light source 23 includes an exposure lamp 23A such as a xenon lamp and a reflector 23B. The first scanning unit 25 moves from the lower side of the second contact glass 11 along the first contact glass 10 from the left to the right in FIG. The second scanning unit 28 is connected to the first scanning unit 25 at a speed ½ that of the first scanning unit 25 so that the optical path between the portion where the document is read and the first photoelectric conversion element 21 is always kept constant. Move in the same direction. A wire (not shown) is wound around the first scanning unit 25 and the second scanning unit 28 and is driven by a first reading scanning system driving motor 30 which is a stepping motor. When the first reading scanning system drive motor 30 rotates forward, it moves in the right direction in FIG. 1, and when the first reading scanning system drive motor 30 rotates in the reverse direction, it moves in the left direction in FIG.
[0026]
The first reading scanning system 20 is used in both the stationary reading mode and the traveling reading mode. In the stationary reading mode, the first scanning unit 25 of the first reading scanning system 20 has the second contact glass of the first contact glass 10 juxtaposed from the position pos1 in FIG. It moves to the position of pos2, which is below the end opposite to the side to be scanned, and the stationary document reading unit 2 performs reading scanning of the document placed on the first contact glass 10. In the traveling reading mode, the first scanning unit 25 of the first reading scanning system 20 is stopped at the position pos 1 in FIG. 1 in order to read the document by the first traveling document reading unit 3.
[0027]
The first light source control board 31 turns on or off the first light source 23 of the first reading scanning system 20 based on a signal from the reading control unit 16.
[0028]
The first reading scanning system driving motor control means 32 controls the first reading scanning system driving motor 30 based on the signal from the reading control unit 16 to control the first scanning unit 25 and the second scanning unit 28 in FIG. Move right or left.
[0029]
The first reading scanning system position sensor group 33 is a plurality of sensors that detect the position of the first scanning unit. The first reading scanning system position sensor group 33 is arranged in the vicinity of the position where the first scanning unit 25 reads the original with the first traveling original reading unit 3 and the position where the first reference white plate 22 can be read. When 25 moves to this position, a reference position signal is output to the reading control unit 16.
[0030]
The reading control unit 16 calculates the position of the first scanning unit 25 based on the reference position signal of the first reading scanning system position sensor group 33 and the number of steps of the first reading scanning system drive motor 30. Then, the first scanning scanning system drive motor 30 is controlled to rotate in the forward and reverse directions so that the first scanning unit 25 and the second scanning unit 28 are reciprocated.
[0031]
The first scanning unit 25 irradiates the original with the first light source 23 during the reading scan, and reflects light from the original toward the second mirror 26 of the second scanning unit 28 via the first mirror 24. reflect. The second scanning unit 25 reflects the reflected light from the first scanning unit 28 toward the first imaging lens 29 via the second mirror 26 and the third mirror 27. The first imaging lens 29 images the reflected light from the third mirror 27 on the light receiving surface of the first photoelectric conversion element 21. The first photoelectric conversion element 21 is constituted by a CCD (Charge Coupled Device) or the like, and outputs an electrical image signal (hereinafter referred to as an image signal) according to the amount of received light.
[0032]
A second reference white plate 42 for performing shading correction of a second photoelectric conversion element 41 of the second reading scanning system 40 described later is disposed on the lower surface of the second contact glass 11.
[0033]
The main body portion 7 includes a document discharge tray 47 on the side, and a document discharge auxiliary roller 55 is formed integrally with the main body portion 7 on the upper surface between the document discharge tray 47 and the second contact glass 11. .
[0034]
The open part 8 of the double-sided image reading apparatus 1 rotates upward with a hinge provided between the main body part 7 and the back side in the direction perpendicular to the paper surface of FIG. 1 is configured such that the upper surface of the main body 7 is opened from the front side. The opening portion 8 is provided with an OC mat 45 so as to come into contact with the first contact glass 10 when the opening portion 8 is closed. The surface of the OC mat 45 facing the first contact glass 10 is white. A document placed on the first contact glass 10 serving as the stationary document reading unit 2 is pressed against the first contact glass 10 by the OC mat 45 and is brought into close contact therewith.
[0035]
A document set tray 46 on which a document to be conveyed and read is placed is formed integrally with the opening 8 at the upper portion of the opening 8. In the portion of the opening 8 facing the second contact glass 11, the document is conveyed from the document set tray 46 to the first traveling document reading unit 3 and the second traveling document reading unit 4. An automatic document feeder 50 for discharging documents is disposed on a discharge tray 47 provided. Further, a second reading scanning system 40 is provided in the vicinity of the automatic document feeder 50, and performs reading scanning of the other surface of the document traveling on the second traveling reading unit 4. The second reading scanning system 40 is configured to be detachable and adjustable by opening and closing an open door 48 provided on the upper portion of the open portion 8.
[0036]
FIG. 3 is a cross-sectional view showing a configuration in the vicinity of the automatic document feeder 50. The automatic document feeder 50 includes a paper feeding unit 51, a separation feeding unit 52, an alignment roller pair 53, and a discharge roller 54, and a carry-in path pas1 between the paper feeding unit 51 and the separation feeding unit 52, separation feeding. A document reading conveyance path which is the first traveling document reading unit 3 and the second traveling document reading unit 4 between the conveyance path pas2 between the section 52 and the alignment roller pair 53 and between the alignment roller pair 53 and the discharge roller pair 54. pas3 is formed.
[0037]
Hereinafter, the configuration and operation of each part of the automatic document feeder 50 will be described.
The paper feeding unit 51 includes a document pressing plate 55 and a paper feeding roller 56, and conveys the document placed on the document setting tray 46 to the separation feeding unit 52. The separation feeding unit 52 includes a separation feeding roller 57 and a separation pad 58. The separation feeding unit 52 separates the originals fed from the paper feeding unit 51 one by one and conveys them toward the alignment roller pair 53. The separating / feeding section 52 includes an electromagnetic clutch on the drive shaft of the separating / feeding roller 57, and a drive system that transmits a driving force from an automatic document feeder driving motor 59 of the automatic document feeder 50 described later. On the other hand, connection and non-connection can be switched.
[0038]
The alignment roller pair 53 includes an electromagnetic clutch on its drive shaft, and can be switched between connection and non-connection with respect to a drive system that transmits a driving force from the automatic document feeder driving motor 59 of the automatic document feeder 50. It has become. The alignment roller pair 53 is stopped until the leading edge of the document fed by the separation feeding unit 52 comes into contact with the document detection sensor and outputs a signal to the reading control unit 16, and the document detection sensor moves to the reading control unit 16. After outputting the signal, the conveyance of the document is started toward the downstream side in the conveyance direction.
[0039]
The second contact glass 11 forms a document reading conveyance path pas 3 between the alignment roller pair 53 and the discharge roller 54. The second reading scanning system 40 is disposed at a position facing the second reference white plate 42 disposed on the lower surface of the second contact glass 11.
[0040]
The discharge roller 54 is provided integrally and rotatably at the end of the opening 8, and together with the discharge auxiliary roller 55 provided integrally and rotatably at the end of the main body 7, the document reading conveyance path pas 3. The document that has passed through is discharged to the document discharge tray 47.
[0041]
The first document detection sensor 61 is upstream of the paper feed roller 56 in the document conveyance direction, the second document detection sensor 62 is upstream of the alignment roller pair 53 in the document conveyance direction, and the third is downstream of the discharge roller 54 in the document conveyance direction. Document detection sensors 63 are respectively arranged. These first to third document detection sensors 61, 62, and 63 (document detection sensor group) transmit the document position to the reading control unit 16, so that the reading control unit 16 controls the conveyance of the document and the on / off of the light source. .
[0042]
Next, the operation of each part of the automatic document feeder 50 will be described with reference to FIG.
The automatic document feeder driving motor control board 65 of the automatic document feeder 50 drives the automatic document feeder 50 by turning on / off the automatic document feeder driving motor 59 that is a stepping motor in accordance with a signal from the reading control unit 16. . In response to an instruction from the automatic document feeder driving motor control board 65, the driving force is transmitted to the above-described paper feeding roller 56, separation feeding roller 57, alignment roller pair 53 and discharge roller 54. The automatic document feeder driving motor 59 can change the rotation speed by a pulse rate from the automatic document feeder driving motor control board 65.
[0043]
The first to third document detection sensors 61, 62, and 63 transmit a signal indicating the arrival of the document to the reading control unit 16 when the document reaches the position where these sensors are arranged. On the other hand, the reading control unit 16 determines whether or not the document is conveyed at an appropriate timing by a signal indicating the arrival of the document from the first to third document detection sensors 61, 62, and 63 and a timer. calculate. If it is determined that the conveyance is defective, a signal indicating that the original is jammed in the carry-in paths pas 1 and pas 2 and the original reading conveyance path pas 3 is sent via the system bus 17 to the system controller 14. To tell.
[0044]
The electromagnetic clutch group 64 for document conveyance is turned on / off by a signal from the reading control unit 16 and is switched between connected and disconnected with respect to each drive system of the automatic document feeder 50 to stop or drive the drive system. I will let you.
[0045]
Next, the second reading scanning system 40 will be described.
The second reading scanning system 40 is provided in the opening part 8 of the double-sided image reading apparatus 1 and reads a document traveling on the second traveling document reading unit 4 in a traveling state. The second reading scanning system 40 includes a second light source 70 composed of an LED (Light Emitting Diode) array that irradiates a document traveling on the second traveling document reading unit 4, and a second photoelectric that outputs an image signal according to the amount of received light. The conversion element 71 and the second reference white plate 42 are included. The second light source 70 is turned on and off in response to an instruction from the second light source control board 72 based on a signal from the reading control unit 16. The second photoelectric conversion element 71 is configured by a CIS (Contact Image Sensor).
[0046]
As described above, the double-sided image reading apparatus 1 has the first reading scanning system 20 and the second reading scanning system 40 arranged on both sides of the document reading transport path pas3, and the document is transported by the automatic document feeder 50 and the document is scanned. Read. Therefore, the images on both sides of the original can be read simultaneously by conveying the original once, and the original can be read at high speed. In the double-sided image reading apparatus 1, when both sides of a document are read, the document is read with the first light source 23 of the first reading scanning system 20 and the second light source 70 of the second reading scanning system 40 turned on.
[0047]
Next, processing of image signals obtained by reading scanning in the single-sided reading mode for reading one side of the original and the double-sided reading mode for reading both sides of the original will be described.
[0048]
The double-sided image reading apparatus 1 separately includes a first image processing unit 5 and a second image processing unit 6 that process image signals read by the first reading scanning system 20 and the second reading scanning system 40. Therefore, one surface and the other surface of the document can be read simultaneously, and the read image signals can be processed simultaneously.
[0049]
The image signals obtained by the reading scan by the first photoelectric conversion element 21 of the first reading scanning system 20 and the second photoelectric conversion element 41 of the second reading scanning system 40 are the first image processing unit 5 and the second image processing unit. 6 is sent to each. Here, the image signal is sent to the image processing relay unit 12 after being subjected to predetermined image processing, and further subjected to predetermined image processing, and then is distinguished for each page via the system bus 17 to be stored in the image memory. 13 is stored.
[0050]
The first image processing unit 5 and the second image processing unit 6 include analog signal processing units 81 and 91, A / D conversion units 82 and 92, shading correction units 83 and 93, filter processing units 84 and 94, and a density conversion unit. 85 and 95, respectively. Each unit of the first image processing unit 5 and the second image processing unit 6 operates based on the control of the reading control unit 16.
[0051]
The analog signal processing units 81 and 91 perform level conversion processing, sample hold processing, and signal amplification processing on the image signals input from the first photoelectric conversion device 21 and the second photoelectric conversion device 41, and the A / D conversion unit 82. , 92. The first photoelectric conversion element 21 and the second photoelectric conversion element 41 are different in the amount of light, the photoelectric conversion efficiency, the output signal level, and the like that the first light source 23 and the second light source 70 irradiate the document. The second photoelectric conversion element 41 is provided with dedicated analog signal processing units 81 and 91, respectively.
[0052]
The A / D conversion units 82 and 92 convert the analog image signals input from the analog signal processing units 81 and 91 into digital image signals, and output the quantized image signals to the shading correction units 83 and 93.
[0053]
The shading correction units 83 and 93 perform black reproduction and white reproduction on the quantized image signals input from the A / D conversion units 82 and 92 and output them to the filter processing units 84 and 94. Here, black reproduction samples and stores the implicit output of the first photoelectric conversion element 21 and the second photoelectric conversion element 41, and reads the first photoelectric conversion element 21 and the second photoelectric conversion at the time of reading a document as read data. By subtracting from the image signal output from the element 41, the influence of the implicit output is reduced. Also, white reproduction is based on the image signal for each pixel when a reference white plate with a uniform reflectance is read, and the image signal at the time of document reading is normalized to each pixel, and the unevenness of light quantity and the influence of optical components This is to correct variations in sensitivity of the first photoelectric conversion element 21 and the second photoelectric conversion element 41.
[0054]
The filter processing units 84 and 94 perform predetermined filter processing on the image signals input from the shading correction units 83 and 93 based on coefficients that determine the filter characteristics set by the reading control unit 16. Specifically, by applying a spatial filtering process, the high frequency component of the image is emphasized and the blur of the image is repaired. That is, the image signal output from the first photoelectric conversion element 21 and the second photoelectric conversion element 41 includes optical components such as lenses and mirrors, aperture openings on the light receiving surfaces of the first photoelectric conversion element 21 and the second photoelectric conversion element 41. There is a deterioration in MTF (Modulation Transfer Function) due to the transfer efficiency and afterimage of the first photoelectric conversion element 21 and the second photoelectric conversion element 41, the integration effect due to physical scanning, the scanning unevenness, and the like. Thus, the deterioration of the MTF is compensated.
[0055]
Since the degree of deterioration of the MTF differs greatly between the first photoelectric conversion element 21 and the second photoelectric conversion element 41, appropriate filter processing units 84 and 94 are provided for the respective filter processes. Further, since the degradation of the MTF is more remarkable in the high frequency region, the filter processing unit performs image edge enhancement processing on the image signal in the high frequency region, thereby repairing the blur and improving the image quality. ing.
[0056]
The density converters 85 and 95 perform density conversion processing on the digital image signals filtered by the filter processors 84 and 94. For example, when an image signal is transmitted by facsimile or when printing is performed with a printing apparatus in which the printing condition is specified to be binarized, the image signal is binarized and the printing condition is multivalued such as a photographic image. In the case of an image signal, the image quality is improved by performing a density conversion process using a density conversion lookup table (density conversion table) having a predetermined density conversion characteristic.
[0057]
  Density converter85,95 includes a RAM (Random Access Memory) control unit and a RAM (not shown), and performs density conversion processing by reading a density conversion table set in the RAM as an address of an input image signal. The image signal for which the density conversion process has been completed is stored in the image memory 13.
[0058]
A specific process for absorbing the image quality difference between the single-sided reading mode (hereinafter referred to as single-sided mode) and the double-sided reading mode (hereinafter referred to as double-sided mode) will be described below. In the single-sided mode, the original is read using one of the first reading scanning system 20 and the second reading scanning system 40, and in the double-sided mode, both the first reading scanning system 20 and the second reading scanning system are used. Scan the document.
[0059]
First, an image signal read when the present invention is not applied will be described with reference to FIGS. As shown in FIG. 4, it is assumed that the amount of light irradiating the original of the first light source 23 of the first reading scanning system 20 or the second light source 70 of the second reading scanning system 40 that irradiates the original in the single-side mode is L1. Here, in the double-sided mode, as in the single-sided mode, an image is read with the light amount irradiating the original of the first light source 23 of the first reading scanning system 20 and the second light source 70 of the second reading scanning system 40 as L1. think of. In the double-sided mode, the original is read in a state where the original is irradiated by the light sources of the two scanning scanning systems, so that the interference from the light source of the other scanning scanning system is received. Accordingly, the first traveling document reading unit 2 and the second traveling document reading unit 3 irradiate the document with a light amount L2 that is brighter than the light amount actually irradiated by the light source. Here, L2 = L1 + α because the light amount is increased by the amount of light α due to the interference of the other light source.
[0060]
When the analog signal processing units 81 and 91 process the image signal when the original is read with the original irradiation light amount as shown in FIG. 4, the original having the same density is read in the single-side mode and the double-side mode as shown in FIG. However, the level of the signal voltage which is an analog image signal is different. This is because the document irradiation light amount in the single-sided mode is L1, and the document irradiation light amount in the double-sided mode is L2, so that the voltage conversion straight line when converting the document density into the signal voltage is different. Therefore, as shown in FIG. 5, the signal voltage when read in the single-side mode is V1, and the signal voltage when read in the double-side mode is V2.
[0061]
When the signal voltage V1 in the single-side mode and the signal voltage V2 in the double-side mode processed by the analog signal processing units 81 and 91 are converted into digital image signals by the A / D conversion units 82 and 92, as shown in FIG. The signal voltage V1 in the single-side mode becomes the output value a1, and the signal voltage V2 in the double-side mode becomes the output value a2. Here, the analog image signal is converted into a 256-step digital image signal from 0 to 255.
[0062]
When the digital image signals converted by the A / D conversion units 82 and 92 are subjected to density conversion processing by the density conversion units 85 and 95, the output value a1 is converted into an output value A1 as shown in FIG. The value a2 is converted into the output value A2. Here, density conversion processing of a multi-tone image signal for emphasizing a halftone is shown. As described above, even when images of the same density are read by the same processing procedure, different image signals are output in the single-side mode and the double-side mode.
[0063]
The double-sided image reading apparatus 1 can absorb a difference in image quality between the double-sided mode and the single-sided mode by selecting and using the following three types of correction methods.
[0064]
First, in the first correction method, the first light source 23 and the second light source control are performed by the reading control unit 16 via the first light source control board 31 so that the reading density is darker in the duplex mode than in the single-sided mode. The light quantity of the second light source 70 is changed through the substrate 72. That is, in the duplex mode, the light amounts of the first light source 23 and the second light source 70 of the first reading scanning system 20 and the second reading scanning system 40 are reduced. Specifically, as shown in FIG. 8, the amount of light irradiating the original of the first light source 23 of the first reading scanning system 20 or the second light source 70 of the second reading scanning system 40 that irradiates the original in the single-side mode is L1. If there is, in the duplex mode, the amount of light that irradiates the document of the first light source 23 of the first reading scanning system 20 and the second light source 70 of the second reading scanning system 40 is L3. If the light quantity due to the interference of the other light source is α, the difference in image quality between the modes can be absorbed by determining the original illumination light quantity in the duplex mode so that L3 + α = L1.
[0065]
As described above, the method of darkening the reading density by reducing the light amount of the light source only needs to perform the process of changing the light amount of the light source. Therefore, there is an advantage that the image processing in the first image processing unit 5 and the second image processing unit 6 can be processed in the same manner in the single-side mode and the double-side mode. Further, it is desirable that the function of changing the light amount of the light source, such as an electric circuit, can control the change amount of the light source with high accuracy.
[0066]
Next, in the second correction method, when the density is converted into the signal voltage in the analog signal processing units 81 and 91 without changing the light amount of the light source, the reading density is darker in the double-sided mode than in the single-sided mode. In this way, an instruction is given from the reading control unit 16 to the analog signal processing units 81 and 91. That is, when the analog image signal obtained by the first photoelectric conversion element 21 and the second photoelectric conversion element 41 is converted into a signal voltage, processing is performed so that the output values are equal in the single-side mode and the double-side mode. Specifically, as shown in FIG. 9, the processing coefficient in the analog signal processing unit is changed so that the signal voltage V2 of the image signal read in the double-sided mode is equal to the signal voltage V1 of the image signal read in the single-sided mode. Let In FIG. 9, the signal voltages output from the analog signal processing units 81 and 91 are made equal by changing the amplification factor when the signal amplification processing is performed by the analog signal processing units 81 and 91. By performing such processing, it is possible to absorb image quality differences between the modes. As described above, the method of changing the processing coefficient in the analog signal processing units 81 and 91 can darken the reading density in the double-sided mode only by setting a value different from the single-sided mode for the analog signal processing coefficient. Differences in image quality between modes can be absorbed.
[0067]
Finally, in the third correction method, the analog image signal is converted into a digital image signal by the A / D conversion units 82 and 92 without changing the light amount of the light source and the analog signal processing coefficient of the analog signal processing units 81 and 91. After the conversion, when density conversion processing is performed on the quantized image signal by the density conversion units 85 and 95, an instruction from the reading control unit 16 is given so that the reading density becomes darker in the double-sided mode than in the single-sided mode. give. Specifically, as shown in FIG. 10, first, the output values a1 of the single-sided mode and the output value a2 of the double-sided mode converted into digital signals by the A / D converters 82 and 92 are converted into the density converters 85 and 95, respectively. Respectively. In the density conversion units 85 and 95, an output value A1 obtained by performing density conversion processing on the output value a1 in the single-sided mode by density conversion processing and an output value A2 obtained by performing density conversion processing on the output value a2 in the double-sided mode by operating the density conversion table. The density conversion line as the density conversion table is changed so that they are equal, that is, A1 = A2. As a result, the image quality difference between the modes can be absorbed. FIG. 10 shows the case where the original to be read has multiple gradations, but the same can be done in the case of binary density conversion. As described above, in the method of changing the density conversion table in the density conversion units 85 and 95, the reading density in the double-side mode can be darkened only by setting a value different from the single-side mode in the density conversion table. The difference in image quality between modes can be absorbed.
[0068]
Hereinafter, the correction processing operation of the double-sided image reading apparatus 1 will be described.
FIG. 11 is a flowchart showing the correction processing operation of the double-sided image reading apparatus 1. In step S1, the user designates the reading mode using the operation unit 18, that is, the duplex mode and the simplex mode, the characteristics of the original to be read, for example, the designation for reading a photograph, and the like. When various types of information are input, the process proceeds to step S2. In step S2, it is determined whether or not the user has instructed to start reading using the operation unit 18 or the like. If it is determined that there is an instruction to start reading, the process proceeds to step S3. In step S3, the reading control unit 16 performs various setting processes for reading a document according to the reading mode and various information specified in step S1, and then proceeds to step S4. In step S4, the reading control unit 16 determines the exposure surface, that is, determines whether the reading mode to be executed is the single-sided mode or the reading mode. Here, in the single-side mode in which only one side is read, the correction processing operation is terminated without performing the correction processing. On the other hand, if the reading mode executed in step S4 is the duplex mode for reading both sides, the process proceeds to step S5. In step S5, the reading control unit 16 selects an optimal correction method based on the reading mode and various information set in step S1.
[0069]
As a method for selecting the optimum method, if the light amount of the light source in the reading mode specified in step S1 is sufficiently high, the first correction method, which is to change the light amount, is adopted.
[0070]
As shown in FIG. 12, a case is considered where the range of light quantity that can be adjusted by the light source is Lmin to Lmax, and the light quantity of the light source in the single-sided mode is low. When the original illumination light amount L1 in the single-sided mode is low and the light source irradiation light amount L2 in the double-sided mode is made equal, the light source light amount L3 in the double-sided mode needs to be set to a value lower than the lower limit value Lmin of the light source. There is. However, since the light amount of the light source cannot be set to a value lower than the lower limit value Lmin, the light source irradiation light amount L2 = L3 + α = Lmin + α in the duplex mode, and L2 and the document irradiation light amount L1 in the single-sided mode cannot be made equal. There is. Therefore, if the light quantity of the light source is low, other correction methods are adopted.
[0071]
  On the other hand, in the response by changing the processing parameter of the analog signal processing unit which is the second correction method, as shown in FIG. 13, when the processing parameter is changed by the analog conversion processing units 85 and 95, the analog signal processing unit The conversion width of the signal voltage output by 85 and 95 is V3 to V4 in the single-sided mode, and V5 to V6 in the double-sided mode. Here, V3 <V5, V4> V6. When the signal voltages output from the analog signal processing units 85 and 95 are converted into digital signals by the A / D conversion units 82 and 92, as shown in FIG. 14, the width of the output value in the single-sided mode is a3 to a4. The width of the output value in the duplex mode is a5 to a6. When density conversion processing is performed on the output values of the A / D converters 82 and 92 by the density converters 85 and 95, as shown in FIG. 15, the width of the output value in the single-side mode becomes A3 to A4, and the double-side mode The width of the output value at that time is A5 to A6. Here, A3 <A5, A4> A6. Therefore, in the double-sided mode, the output value width is smaller than that in the single-sided mode, so that gradation is deteriorated. As described above, if the processing coefficient of the analog signal is changed, the gradation of the finally obtained image signal may be deteriorated. Therefore, it is not suitable when gradation is required when reading a document such as a photograph. is there. Therefore, the reading mode specified in step S1 has halftone reproducibility.requestWhen a document such as a photograph to be exposed is exposed, the third correction method for changing the density conversion processing table is used rather than the second correction method for changing the processing coefficient of the analog signal that may impair the gradation. adopt.
[0072]
Further, in correspondence with changing the density conversion table as the third correction method, as shown in FIG. 16, if the density conversion line in the single-side mode is shifted as it is so that the reading density becomes dark in the double-side mode, the A / D A portion where the output values of the conversion units 82 and 92 are high cannot be expressed. Therefore, in the portion where the output values of the A / D converters 82 and 92 are high, it is necessary to change the density conversion characteristics from the other portions as shown in FIG. Therefore, the density conversion characteristics are different in this portion, and the density conversion units 85 and 95 perform correction processing on the already multi-valued image signal. Therefore, the multi-value conversion processing in the A / D conversion processing units 82 and 92 is performed. It is impossible to reproduce the bright part information of the document rounded in step. For this reason, it may become inappropriate when exposing a document with a light source having a high light quantity or when exposing a document with a low density. Therefore, when the original is exposed with the light source amount increased by the reading information specified in step S1 or when the original with a low density is exposed, the A / D conversion processing unit obtains the name information of the original. A second correction method for changing a processing coefficient of an analog signal to be corrected before AD conversion is adopted rather than a method of changing a density conversion table for performing correction processing after being rounded.
[0073]
If it is determined in step S5 that the selected correction method is the first correction method by manipulating the light amount of the document, the process proceeds to step S6. In step S6, the light source light source is set low so that the reading density becomes dark, that is, the image density becomes low, and the document reading processing operation is terminated.
[0074]
On the other hand, if the selected correction method is the first correction method for changing the processing coefficient of the analog signal in step S5, the process proceeds to step S7. In step S7, correction processing is performed on the processing coefficient of the analog signal so that the reading density becomes dark, that is, the image density becomes low, and the document reading processing operation is finished.
[0075]
If it is determined in step S5 that the selected correction method is the third correction method for changing the density conversion table, the process proceeds to step S8. In step S8, the digital image signal is corrected so that the reading density becomes dark, that is, the image density becomes low, and the original reading processing operation is finished.
[0076]
As described above, the double-sided image reading apparatus 1 selects one correction method from the three correction methods according to the reading mode and document information, and corrects the reading density, whereby the image quality difference between the double-sided mode and the single-sided mode is corrected. Can be absorbed.
[0077]
  MaThe double-sided image reading apparatus 1 described above can be applied to reading of originals such as facsimile machines and copying machines.
[0078]
In the double-sided image reading apparatus 1, the second reading scanning system 40 that reads the other surface of the document is fixed, the first reading scanning system 20 that reads one surface of the document is also stopped, and both sides of the document are conveyed while the document is being conveyed. Although it is configured to read, the second reading scanning system 40 is configured to be movable, and the first reading scanning system 20 and the second reading scanning system 40 are scanned in a state where the document is stationary on the first contact glass 21. Thus, it is possible to read both sides of the document. The first reading scanning system 20 is a reading unit for a reduction optical system, and the second reading scanning system 40 is a reading unit for an equal magnification optical system. Both the first reading scanning system 20 and the second reading scanning system 40 are used. May be used as the reading unit of the reduction optical system, or both may be used as the reading unit of the equal-magnification optical system. Also, the first reading scanning system 20 may be used as the reading unit of the equal-magnification optical system, and the second reading scanning system 40 may be used. The reading unit of the reduction optical system may be used.
[0079]
【The invention's effect】
  As described above, according to the present invention, when the reading means arranged on one side and the other side of the original reads both sides of the original at the same time with the respective light sources turned on, The correction means corrects the reading density of each reading means to be darker than when reading one side of the original with one of the reading means arranged illuminating the light source. Therefore, the scanned images can be made equal when scanning both sides of the document simultaneously and when scanning one side of the document.The When scanning images on both sides of the document, the amount of light from the light source is reduced in consideration of interference from the other light source, thereby reducing the show-through that occurs when both sides are scanned simultaneously.can do. Moreover, when reading both sides simultaneously, the light source of the pair of reading means is turned on, and when reading one side, the light source of one reading means is turned off and the power saving is measured. A read image can be obtained.
[0080]
  The correction means includes first to third correction means. The first correction means isWhen reading images on both sides of the document, the reading density is stabilized because the image is read with the light amount of the light source lowered in consideration of interference from the other light source. Further, it is not necessary to perform processing on the read image only by reading the image with the light amount reduced.
[0081]
  ReadingThe capturing unit includes a photoelectric conversion unit that obtains an electrical signal corresponding to the amount of received light, thereby receiving the reflected light from the document irradiated by the light source and converting it into an analog electrical signal.SecondWhen reading both sides of the document at the same time, the correction unit performs signal processing, such as an amplification factor, on the analog electric signal obtained by the photoelectric conversion unit so that the reading density is darker than when reading one side of the document. The reading density is stabilized by performing the changing process.
[0082]
  ThirdThe correction means converts the analog electrical signal obtained by the photoelectric conversion means into a digital electrical signal so that when reading both sides of the document simultaneously, the reading density is darker than when reading one side of the document. By performing density conversion processing by changing density conversion characteristics, the read density is stabilized.
  The selection means selects one of the first to third correction means based on the characteristics of the document such as designation when reading a photograph by the input means and the reading conditions such as reading the document lightly or darkly. The correction unit can perform reading suitable for the document by performing correction by any one of the first to third correction units selected by the selection unit.
[0083]
  The correction means is selected by the light quantity of the light source.Is high enoughIf this is the case, select the first correction means and the amount of light from the light source.Is lowWhen the original image with low density is read, the second correction means is selected and the light quantity of the light sourceIs lowIn addition, when reading a document image that requires halftone reproducibility, it is possible to perform reading suitable for the document by selecting and correcting the third correction means.
[Brief description of the drawings]
FIG. 1 is a schematic cross-sectional view showing a configuration of a double-sided image reading apparatus 1 according to an embodiment of the present invention.
FIG. 2 is a functional block diagram showing an electrical configuration of the double-sided image reading apparatus 1;
3 is a cross-sectional view showing a configuration in the vicinity of the automatic document feeder 50 of the double-sided image reading apparatus 1. FIG.
FIG. 4 is a comparison diagram of the amount of document irradiation light in the single-side mode and the double-side mode when the present invention is not applied.
FIG. 5 is a conversion diagram in an analog signal processing unit when the present invention is not applied.
FIG. 6 is a conversion diagram in an A / D conversion processing unit.
FIG. 7 is a conversion diagram in a density conversion unit when the present invention is not applied.
FIG. 8 is a comparison diagram of the amount of document irradiation light in the corrected single-sided mode and double-sided mode.
FIG. 9 is a conversion diagram in the analog signal processing unit after correction.
FIG. 10 is a conversion diagram in a density conversion unit after correction.
FIG. 11 is a flowchart showing a correction processing operation of the double-sided image reading apparatus 1;
FIG. 12 is a diagram for explaining a corresponding defect due to a change in light amount;
FIG. 13 is a diagram for explaining a corresponding defect due to a processing coefficient of an analog signal.
FIG. 14 is a diagram for explaining a corresponding defect due to a processing coefficient of an analog signal.
FIG. 15 is a diagram illustrating a corresponding defect due to a processing coefficient of an analog signal.
FIG. 16 is a diagram for explaining a corresponding defect by the density conversion table;
FIG. 17 is a diagram for explaining a corresponding defect by a density conversion table.
[Explanation of symbols]
1 Double-sided image reader
5 First image processing unit
6 Second image processing unit
16 Reading control unit
20 First reading scanning system
21 1st photoelectric conversion element
23 First light source
40 Second scanning system
41 Second photoelectric conversion element
70 Second light source
81, 91 Analog signal processor
82,92 A / D converter
85,95 Density converter

Claims (1)

A reading unit having a light source for exposing the document and a photoelectric conversion unit for obtaining an electric signal corresponding to the amount of received light is disposed on one surface side and the other surface side of the document, and light is emitted from the light source to the document. In a double-sided image reading apparatus that reads images on both sides of the original,
Input means for inputting the characteristics of the original and the reading conditions of the original;
When the pair of reading means simultaneously reads both sides of the original with the respective light sources turned on, the reading when one of the reading means turns on one of the light sources and reads one side of the original is performed. Correction means for correcting the reading density of the reading means to be darker when reading both sides of the document with the respective light sources of the reading means turned on than the reading density of the means,
The correction means includes
A first correction unit that darkens a reading density of the reading unit by changing a light amount of a light source of the reading unit;
A second correction unit that darkens the reading density of the reading unit by changing an amplification factor with respect to an analog electric signal obtained by the photoelectric conversion unit;
Third correction means for darkening the reading density of the reading means by changing density conversion characteristics for performing density conversion processing after converting an analog electric signal obtained by the photoelectric conversion means into a digital electric signal When,
Based on the reading conditions of features and the document of the document input by said input means, when the light quantity of the light source is sufficiently not high, selects the first correction means for setting a low light intensity of the light source When reading the original with a low light intensity of the light source and a low density, the second correction unit is selected to read the original with a low light intensity of the light source and which requires halftone reproducibility. The double-sided image reading apparatus further comprises selection means for selecting the third correction means.

Images