JP2005094200A - Original reading apparatus, computer program, original reading system, and original reading method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an original reading apparatus or the like for making adjustment of an output value from an image sensor in a short period of time. <P>SOLUTION: The apparatus has a light source for switching and emitting a plurality of colors of lights, and the image sensor for outputting signals corresponding to a light quantity received within a predetermined time. In this apparatus, the signal of the image sensor by the plurality of colors of lights at the time of irradiating the original is amplified at a predetermined amplification rate, the value of the amplified signals are adjusted so that they may become predetermined values, then the light source emits a light to irradiate the original with the light, the signal for each color is outputted from the image sensor, and the original is read so that the value of the signal by the lights of a plurality of colors of lights continuously outputted may correspond to a single pixel. In this apparatus, in the adjustment, the value of the signal after amplification by the light of color in which the value of the signal is the smallest is adjusted so as to be the first value, among the values of the signals each having emitted the plurality of colors of lights in the same light-emitting time. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

  The present invention relates to an original reading apparatus, a computer program, an original reading system, and an original reading method using a light source that emits light of a plurality of colors.

  As a document reading apparatus using a light source that emits light of a plurality of colors, three LEDs (light emitting diodes) each emitting light of R (red), G (green), and B (blue) colors are sequentially switched and turned on. A color scanner is known that reads a document by a signal that is emitted in accordance with the amount of light received by an image sensor. In such a color scanner, signals of three colors become information corresponding to one pixel. For this reason, the color of one pixel is determined by the balance of signals by the three colors of light reflected from the document. That is, since the reflected light from the white original is in a state where the three colors of light are superimposed in a well-balanced manner, the values of the three color signals from the reflected light from the white original must be substantially equal. For this reason, before reading the original, the three color LEDs are sequentially switched to irradiate the white original, and the output value is adjusted so that the values of the output signals are substantially equal.

  In the conventional adjustment, first, the first color LED is caused to emit light for a predetermined time, reflected by a white original, and received by a image sensor. At this time, since the output voltage of the image sensor is offset by the dark current, an offset adjustment for removing this offset is performed. The output voltage after the offset adjustment is amplified by an amplifier at an amplification factor such that it becomes a voltage value V that can be converted by an analog / digital converter (hereinafter referred to as A / D converter). For example, when the amplified output voltage is converted into 8-bit data, the A / D converter sets the maximum voltage value (white level) to “255” and the minimum voltage value (black level) to “0”. The first color adjustment is completed.

  Next, after the LED of the second color is caused to emit light and offset adjustment is performed, the amplifier is amplified with the same amplification factor as that of the first color, and the output voltage value is detected. At this time, if the detected voltage value is smaller than the voltage value V that can be converted by the A / D converter, the light emission time of the second color LED is lengthened, and the offset adjustment is again made to the output voltage of the image sensor. Then, it is amplified by an amplifier and adjusted so that the output becomes a voltage value V. On the other hand, when the detected value is larger than the voltage value V, the amplification factor of the amplifier is adjusted so that the voltage value V can be converted by the A / D converter. At this time, since the output of the first color is reduced and an offset is generated by changing the amplification factor, the same adjustment as in the case of the LED of the second color is performed with respect to the output of the image sensor by the LED of the first color. The light emission time of the first color LED is adjusted so that the output of the image sensor from the first color LED becomes the voltage value V.

Next, for the third color LED, the same adjustment as that for the second color LED is performed. At this time, when the detected voltage value is smaller than the voltage value V that can be converted by the A / D converter, the light emission time of the LED of the third color is lengthened so that the output becomes the voltage value V. adjust. When the detected voltage value is larger than the voltage value V, the amplification factor of the amplifier is adjusted so that the voltage value V can be converted by the A / D converter. At this time, by changing the amplification factor, the output of the first color and the second color is reduced and an offset is also generated. Therefore, the output of the image sensor by the LEDs of the first color and the second color is compared with the output of the third color. The same adjustment as in the case of the LED is performed.
JP-A-11-168601

  However, in the above-described adjustment, it is necessary for the above-described color scanner to repeatedly perform offset adjustment and adjustment of the amplification factor of the amplifier with respect to the output of the image sensor by sequentially emitting LEDs from the first color. These adjustments are repeated at least three times at least once for each color, and six times if there are the most, and a great deal of time is consumed. In particular, the LED is used for the purpose of shortening the warm-up time of the color scanner. However, if the adjustment is performed during the warm-up, there is a problem that the warm-up time cannot be shortened even if the LED is used as a light source.

  The present invention has been made in view of such problems, and realizes a document reading apparatus, a computer program, a document reading system, and a document reading method capable of adjusting an output value from an image sensor in a short time. There is.

  The main invention has a light source for sequentially switching and emitting light of a plurality of colors to irradiate a document, and an image sensor for outputting a signal according to the amount of light received within a predetermined time, Amplifying the signal of the image sensor by the light of the plurality of colors at the time of irradiating the original with a predetermined amplification factor, adjusting the value of the amplified signal to a predetermined value, and then adjusting the light source A document reading device that emits light to irradiate a document, outputs the signal for each color from the image sensor, and reads the document in correspondence with the value of the signal by a plurality of colors of light output continuously corresponding to one pixel In the adjustment, among the signal values when light of a plurality of colors is emitted in the same light emission time, the value of the signal after the amplification by the light of the color that minimizes the signal value is First, adjust to a predetermined value It is a document reading apparatus according to claim.

  Other features of the present invention will be clarified by the description of the present specification and the accompanying drawings.

  According to the present invention, it is possible to realize a document reading apparatus, a computer program, a document reading system, and a document reading method capable of adjusting an output value from an image sensor in a short time.

  At least the following will be made clear by the description of the present specification and the accompanying drawings.

  A light source for irradiating a document by sequentially switching light of multiple colors and an image sensor for outputting a signal according to the amount of light received within a predetermined time At the time, the signal of the image sensor by the light of the plurality of colors is amplified at a predetermined amplification factor, adjusted so that the value of the amplified signal becomes a predetermined value, and then the light source is caused to emit light. In the document reading apparatus that irradiates a document, outputs the signal for each color from the image sensor, and reads the document in correspondence with a value of the signal by a plurality of light beams that are continuously output corresponding to one pixel, the adjustment At the time, among the signal values when emitting light of a plurality of colors in the same light emission time, the value of the signal after the amplification by the light of the color that minimizes the value of the signal, first, It is characterized by adjusting to a predetermined value That is a document reading device.

  The value of the signal when light of a plurality of colors is emitted in the same light emission time differs depending on the light of each color. Therefore, when the signal is amplified with an amplification factor according to the light of any color, the signal of the other color is used. There is a possibility that the value of becomes a value outside the expected range. In this case, the amplification factor is changed in accordance with light of an unexpected color, and adjustment is performed again. According to the above document reading device, the signal value when each of the plurality of colors of light is emitted in the same light emission time is acquired in advance, and the signal value among the acquired signal values is the smallest. Since the value of the amplified signal by the light of the color is first adjusted to be a predetermined value, the value of the signal by the light of any color can be set to a value within the assumed range. . Therefore, the adjustment of the signal value by the light of each color does not need to be repeated by changing the amplification factor, so that the time spent for adjustment can be shortened and the adjustment of the output value from the image sensor can be executed in a short time. Is possible.

  Further, the light color to be adjusted first is light of the color that minimizes the signal value among the signal values when the light of a plurality of colors is emitted in the same light emission time. Even when a light source such as an LED that is used as a light source of electric power is used, there is no need to change the amplification factor and repeat the operation. It is valid.

In such a document reading apparatus, it is desirable that the adjustment is performed by adjusting the amplification factor so that the value of the amplified signal by the color light having the minimum signal value becomes a predetermined value.
There are multiple colors of light sources, each with different output levels. On the other hand, there is one image sensor, and it is complicated to control the output level for each color of light. For this reason, as in the above document reading apparatus, by adjusting the signal amplification factor, it is possible to adjust the amplification factor to cope with light of a color that is difficult to obtain a desired value. It is possible to easily secure a desired value of the signal of the image sensor by light.

In such a document reading device, the color having the minimum signal value based on the ratio of the signal values of the image sensor by the light of each color when the light of a plurality of colors is emitted in the same light emission time. It is desirable to determine each light emission time of the other color so that the value of the amplified signal by the light of the other color excluding the light of a predetermined value becomes a predetermined value.
According to such a document reading apparatus, it is not necessary to adjust the value of the signal of the image sensor for all colors of light, and the image sensor signal first outputs light of each color with the same light emission time. It is only necessary to emit and output each. Further, the adjustment is performed only for the first light of one color, and the lights of the other colors are determined based on the ratio of the signals that are first emitted with the same light emission time and output. It is possible to adjust to an almost appropriate value. For this reason, it is possible to shorten the adjustment time as compared with the case where light is emitted for each color and the light is sequentially adjusted.

In such a document reading apparatus, after the light emission time of each color light is determined, the light of the plurality of colors is sequentially switched and emitted so that the value of the amplified signal by the light of each color becomes the predetermined value. It is desirable to finely adjust each light emission time.
According to such a document reading apparatus, the value of the signal of the image sensor by the light of the other color determined based on the ratio of the signals emitted and output by the respective colors in the same light emission time is the predetermined value. Even if it is different from the above, it is possible to adjust accurately by fine adjustment.

In the document reading apparatus, the document is a white document, and the value of the amplified signal is converted into digital information by an analog / digital converter, and the predetermined value is converted into the analog / digital converter. It is desirable that the upper limit value be converted by a vessel.
According to such a document reading apparatus, since white is a state in which the primary colors of light are mixed in the same amount for each color in a balanced manner, the output level of light of each color can be easily adjusted by making the document white. Is possible. Also, since white is the state where the output of light of each color is maximized, the value of the signal after amplification when illuminating a white document is set as the upper limit of the value that can be converted by the analog / digital converter. Thus, the bit resolution after analog / digital conversion can be increased, and a high-performance document reading apparatus can be realized.

And a light source for irradiating the document by sequentially switching light of a plurality of colors and an image sensor for outputting a signal corresponding to the amount of light received within a predetermined time. The signal of the image sensor by the light of the plurality of colors at the time of irradiation is amplified at a predetermined amplification factor, adjusted so that the value of the amplified signal becomes a predetermined value, and then the light source emits light In an original reading apparatus for reading an original by irradiating an original, outputting the signal for each color from the image sensor, and corresponding the value of the signal by a plurality of colors of light output continuously to one pixel, The original is a white original, and the amplification by the light of the color that minimizes the signal value among the signal values when light of a plurality of colors is emitted at the same emission time during the adjustment. The signal value after the first, given The amplification factor is adjusted so that the signal value after the amplification is converted into digital information by an analog / digital converter, and the predetermined value is converted by the analog / digital converter. The upper limit of possible values, and the value of the signal is the minimum based on the ratio of the signal values of the image sensor by the light of each color when the light of a plurality of colors is emitted in the same light emission time. The light emission times of the other colors were determined so that the value of the amplified signal by the light of other colors excluding the light of the color to be a predetermined value, and the light emission time of the light of each color was determined An original reading apparatus characterized in that the light of the plurality of colors is sequentially switched and emitted, and each light emission time is finely adjusted so that a value of the amplified signal by the light of each color becomes the predetermined value; is there.
According to such a document reading apparatus, all of the effects described above can be achieved, so that the object of the present invention can be achieved most effectively.

  And a light source for irradiating the document by sequentially switching light of a plurality of colors and an image sensor for outputting a signal corresponding to the amount of light received within a predetermined time. The signal of the image sensor by the light of the plurality of colors at the time of irradiation is amplified at a predetermined amplification factor, adjusted so that the value of the amplified signal becomes a predetermined value, and then the light source emits light A document reading device that irradiates a document, outputs the signal for each color from the image sensor, and reads the document in correspondence with a value of the signal by a plurality of colors of light that are continuously output corresponding to one pixel; During the adjustment, among the signal values when light of a plurality of colors is emitted at the same light emission time, the value of the amplified signal by the light of the color that minimizes the signal value is Realizes a function to adjust to a predetermined value Because of the computer program can also be realized.

  A computer main body and a light source connected to the computer main body for sequentially switching and emitting light of a plurality of colors to irradiate a document and a signal corresponding to the amount of light received within a predetermined time are output. An image sensor for amplifying the signal of the image sensor by the light of the plurality of colors at a predetermined amplification factor when the original is irradiated, and the value of the signal after the amplification is a predetermined value After adjusting so that the light source emits light, the original is irradiated, the signal for each color is output from the image sensor, and the value of the signal by the light of a plurality of colors that are continuously output is set to one pixel. In the original reading system having an original reading apparatus that reads an original corresponding to the signal, the value of the signal is the smallest among the signal values when light of a plurality of colors is emitted in the same light emission time during the adjustment. The color to be The value of the signal after the amplification by the light, first, original reading system characterized also feasible to be adjusted to a predetermined value.

  In addition, a light source that sequentially switches light of a plurality of colors emits light of the plurality of colors in the same emission time, irradiates the document, and outputs a signal corresponding to the amount of light received within a predetermined time And outputting the value of the signal by each light in the image sensor for performing, and among the values of the signal by the respective light, the image sensor by the color light that minimizes the value of the signal Amplifying the signal at a predetermined amplification factor, and adjusting the value of the amplified signal to a predetermined value first; illuminating the original by emitting the light source; and A document reading method comprising: outputting the signal for each color from a sensor, and reading the document by associating a value of the signal by a plurality of colors of light output in succession with one pixel. It is feasible.

=== Overall Configuration of Document Reading Apparatus ===
FIG. 1 is an explanatory diagram showing a schematic configuration of a color scanner 10 as an example of a document reading apparatus according to the present invention.

  The color scanner 10 includes a document table glass 7 on which the document 5 is placed, a document table cover 6 for pressing the reading surface of the document 5 placed on the document table glass 7 toward the document table glass 7, A carriage 16 as a moving body that faces the document glass 7 and moves along the document 5 while maintaining a certain distance from the document 5, a driving means 18 for moving the carriage 16, and the carriage 16 in a stable state And a control guide 50 for driving and controlling each element of the color scanner 10.

  The carriage 16 has a light source unit 8 as a light source for irradiating the document 5 with light of three colors via the document table glass 7, a rod lens array 14 for condensing the reflected light from the document 5, and a reflection transmitted through the lens. A contact-type image sensor unit integrally configured with a linear CCD sensor 15 as an image sensor that receives light as light amount information and outputs the light amount information as a signal, and a guide receiver that engages with the regulation guide 20 A portion 29 is provided. In the present embodiment, an example in which a CIS (Contact Image Sensor) 1 is used as a contact image sensor unit will be described. Details of CIS1 will be described later.

  The regulation guide 20 is provided along the direction in which the carriage moves (hereinafter referred to as the movement direction), and is formed of a stainless steel cylindrical material. The restriction guide 20 is provided on the carriage 16 and passes through two guide receiving portions 29 made of thrust bearings. By increasing the distance in the moving direction of the two guide receiving portions 29 provided on the carriage 16, the carriage 16 can be moved more stably.

  The driving means 18 includes an annular timing belt 181 fixed to the carriage 16 and a pulley 182 that meshes with the timing belt 181, and a pulse motor 183 disposed on one end side in the moving direction, and on the other end side. An idler pulley 184 that is arranged and applies tension to the timing belt 181 is configured. The pulse motor 183 is driven by the motor driver 217 of the control unit 50, and the read image can be enlarged and reduced in the moving direction by the moving speed of the carriage 16 changed according to the rotational speed of the pulse motor 183. It becomes.

  In the color scanner 10, the light source unit 8 sequentially emits light of three colors of red (R), green (G), and blue (B) to irradiate the document 5, and the reflected light is emitted from the rod lens array 14. The carriage 16 is moved along the document 5 while being condensed on the linear CCD sensor 15. The color scanner 10 reads an image corresponding to the distance moved by the carriage 16 during one cycle by taking in a voltage value as light amount information indicating the amount of light received by the linear CCD sensor 15 at a predetermined cycle. At this time, three pieces of light quantity information of R component, G component, and B component are taken in as data for one line. This light quantity information is output as a signal to the AFE unit 23 described later.

=== Configuration of Control Unit ===
FIG. 2 is a block diagram illustrating an example of the control unit 50.
The control unit 50 of the color scanner 10 includes a CPU 54 as a control unit that controls the entire color scanner 10, a program for controlling each unit of the color scanner 10, a ROM that stores various data, a program, and various data Are temporarily stored, a memory 28 such as a rewritable EEPROM, a light source driver 22 for controlling the light source to emit light, a sensor driver 25 for driving the linear CCD sensor 15, and a linear CCD sensor 15 includes an AFE unit 23 to which a signal output from 15 is input, a digital signal processing unit 24 for converting the output from the AFE unit 23 into predetermined digital image data, and a pulse motor 183 for moving the carriage 16. Motor driver 217 for driving and external host computer (not shown) And a interface 52 as input and output means.

The sensor driver 25 is a circuit that controls the drive of the linear CCD sensor 15, and is a circuit that controls the on / off of the MOS transistor switch and the reading of the charge accumulated in the light receiving element.
The motor driver 217 is a drive circuit for driving a pulse motor 183 for moving the carriage 16 at a predetermined speed. In the carriage 16, the power of the pulse motor 183 driven by the motor driver 217 is transmitted to the carriage 16 by the timing belt 181 and moves in the moving direction.

  The AFE (Analog Front End) unit 23 includes an analog signal processing unit 23a, an A / D converter 23b, and the like. The analog signal processing unit 23a performs signal processing such as noise reduction processing including amplification and offset correction on the analog image signal output from the CIS 1 and outputs the image signal. The A / D converter 23b quantizes the image signal output from the analog signal processing unit 23a into digital image data of a digital representation having a predetermined bit length, and outputs the digital image data.

  The digital signal processing unit 24 performs processes such as gamma correction, defective pixel interpolation by a pixel interpolation method, shading correction, and image signal sharpening on the digital image data output from the AFE unit 23. Note that the various processes performed by the digital signal processing unit 24 may be replaced with processes by a computer program executed by the CPU 54. Digital image data that has been subjected to various processes by the digital signal processing unit 24 is temporarily stored in the memory 28, and when a certain amount of data is accumulated, it is transferred to a personal computer or the like via the interface 52.

=== Configuration of CIS (Contact Image Sensor Unit) ===
FIG. 3 is a diagram for explaining the configuration of the CIS, and FIG. 4 is a side view of the CIS.
The CIS 1 includes a light source unit 8 as a light source including an LED (light emitting diode) 11, a rod lens array 14 as an imaging optical system, and a linear CCD sensor 15 in which light receiving elements are arranged in a line.

  The light source unit 8 includes an LED 11r including an LED 11r that emits red (R) light, an LED 11g that emits green (G) light, and an LED 11b that emits blue (B) light in order to enable reading of a color image. A light guide 12 and a light guide cover 13 are provided. For example, in the light source unit 8 of this embodiment, as shown in the drawing, the LEDs 11r, 11g, and 11b have light emitted from the LEDs 11r, 11g, and 11b on the one end surface 12a side in the longitudinal direction Y of the light guide 12, and the end surface 12a. Is positioned and attached so as to enter the light guide 12. Here, the longitudinal direction Y of the light guide 12 is a direction orthogonal to the moving direction of the carriage 16, that is, a direction in which a plurality of light receiving elements of the linear CCD sensor 15 are arranged. Say.

  The light guide 12 is formed of a light transmissive member such as glass. The light guide 12 has a diffusion surface 12b (see FIG. 4) and an emission surface 12c. The diffusion surface 12b is formed in a wave shape. The exit surface 12 c is disposed in the opening 13 a of the light guide cover 13 in the light guide 12. The exit surface 12c is formed in a lens shape, and emits the light scattered by the diffusion surface 12b in the direction of irradiating the area above the rod lens array 14 in the document. As a result, light is emitted in a predetermined direction and the original is irradiated. When the exit surface 12c is formed into a lens shape, the document above the rod lens array 14, that is, the range including the document reading area, can be illuminated more brightly than when the lens 12 is not formed into a lens shape.

  The light guide cover 13 is formed of, for example, a white light-impermeable member having good light reflectivity, and is attached so as to cover the outside of the light guide 12 through an air layer. The light guide cover 13 returns the light leaked from the light guide 12 in a direction different from the predetermined direction into the light guide 12 again. When the light guide cover 13 is attached, the light use efficiency can be improved.

  The rod lens array 14 has a plurality of cylindrical lenses (rod lenses) 14a arranged in a line along the element arrangement direction. The rod lens 14a is disposed vertically above the linear CCD sensor 15, and is provided in one-to-one correspondence with a light receiving element described later. The rod lens array 14 receives the reflected light from the original and forms an image of the reading area of the original located immediately above it on the linear CCD sensor 15 as an optical image at the same magnification as the original by the rod lens 14a.

  The linear CCD sensor 15 includes a plurality of light receiving elements, MOS transistor switches, and the like arranged linearly along the longitudinal direction of the CIS 1 immediately below the rod lens array 14. The linear CCD sensor 15 takes in the density of the optical image formed by the rod lens array 14 as light quantity information at a predetermined cycle, and outputs an electrical signal correlated with the light quantity information. Thereby, the optical image is converted into an electric signal. The linear CCD sensor 15 accumulates charges obtained by photoelectric conversion of light in a predetermined wavelength region such as visible light, infrared light, and ultraviolet light in a light receiving element such as a photodiode for a certain period of time, and the amount of light received for each light receiving element. An electrical signal corresponding to the output is output using a MOS transistor switch.

Next, the operation of the light guide 12 will be described.
FIG. 5 is a schematic diagram showing a state in which light emitted from the LED 11 is guided in the longitudinal direction Y of the light guide 12 and emitted in a predetermined direction to irradiate the original. FIG. 6 shows an optical image formed on the linear CCD sensor. It is a figure for demonstrating a mode that it is imaged. Light emitted from the LED 11 of the light source enters the light guide 12 from the end surface 12a of the light guide 12, and is guided in the longitudinal direction Y of the light guide 12 while repeating internal reflection. When the guided light is incident on the diffusion surface 12b, the incident light is diffused or reflected, and a part of the light is emitted from the emission surface 12c. As shown in FIG. 6, the light emitted from the exit surface 12 c irradiates a region of the document 5 located above the rod lens array 14 and the linear CCD sensor 15. The irradiated light is reflected by the original and enters the rod lens array 14 and forms an image on the linear CCD sensor 15. At this time, an optical image of the reading area of the document located above the linear CCD sensor 15, that is, an optical image for one line is captured at a predetermined cycle by the linear CCD sensor 15, and corresponds to the received light amount for each light receiving element An electrical signal is output.

=== Color Scanner Reading Operation ===
FIG. 7 is a flowchart showing the reading operation of the color scanner.

  When the original 5 is placed on the platen glass 7 and the reading start command is received together with the reading area designation information, the color scanner 10 starts reading processing under the control of the control unit 50 (S102). First, the carriage 16 is moved to a predetermined position outside the document placement area (S104), and the output of the linear CCD sensor 15 by the light of each color is adjusted (S106). Adjustment of the output of the linear CCD sensor 15 will be described later.

  When the adjustment of the output of the linear CCD sensor 15 is completed, the carriage 16 is moved at a predetermined speed in the moving direction, and when the end of the reading area is positioned vertically above the linear CCD sensor 15, reading processing is started (S108). .

  In the reading process, the linear CCD sensor 15 takes in the light amount received by each light receiving element at a constant period by the sensor driver 25 as light amount information, and outputs an electrical signal correlated with the light amount information.

  On the other hand, the carriage 16 is moved at a predetermined speed by a stepping motor 183 driven by a motor driver 217, while the LED 11 sequentially emits light of three colors of R, G, and B. At this time, the LED 11 is controlled such that the LED 11 of any color emits once during the period in which the linear CCD sensor 15 captures light amount information (hereinafter referred to as the capture period). Since the optical image of each color component is projected on the linear CCD sensor 15 while the light of each color is irradiated, the linear CCD sensor 15 uses the light intensity information on the density of the projected optical image of the three colors. Are sequentially captured and output electrical signals correlated with light quantity information by light of each color. At this time, the output of each light receiving element by the three color optical images projected continuously is an electric signal corresponding to one pixel, and the entire linear CCD sensor 15 has an electric power corresponding to one line in the element array direction. Signal.

  The reading process for one line is continuously performed while the carriage 16 is moved (S110), and an electric signal for one line in the element arrangement direction based on the three-color optical image captured by the linear CCD sensor 15 is Sequentially output to the AFE unit 23 and converted into digital image data as digital information (S112). The digital image data output from the AFE unit 23 is subjected to various processes by the digital signal processing unit 24 (S114). The processed digital image data is transferred to a personal computer or the like (not shown) via the interface 52 (S116).

  When the carriage 16 passes the area designated by the designation information of the reading area (S118), the capturing of the light amount information by the linear CCD sensor 15 is finished (S120). Thereafter, the carriage 16 moves to a predetermined position and the reading process is finished (S122).

=== Adjustment of output signal of linear CCD sensor ===
Digital image data for one pixel read by the color scanner 10 is generated based on the output of each light receiving element of the linear CCD sensor 15 using light of three colors. That is, the color of one pixel of the digital image data is determined by the balance of the output of each light receiving element when each of the three colors of light is emitted. For this reason, it is necessary to adjust the output of each light receiving element for the same document when each of the three colors of light is emitted, based on a predetermined reference before starting to read the document 5.

  In addition, the LED 11 used as a light source has low power consumption and is easy to control as compared with a fluorescent lamp or the like, but has low luminance. For this reason, the signal output from the linear CCD sensor 15 is weak. On the other hand, the signal output from the linear CCD sensor 15 is input to the A / D converter 23b for conversion into digital image data, but the bit in the digital image data after being converted by the A / D converter 23b. In order to increase the resolution, it is desirable to input the maximum value of the convertible signal value to the A / D converter 23b. For this reason, the value of the signal input to the A / D converter 23b by the light of each color is adjusted to be the maximum value of the signal that can be converted by the A / D converter 23b.

  As a method of adjusting the value of the signal input to the A / D converter 23b, a method of changing the amplification factor of the signal output from the linear CCD sensor 15 and the output of each color LED 11r, 11g, 11b are changed. There is a method. As described above, since the luminance of the LED 11 is small, even if the output of the LED 11 is increased to the maximum, the maximum value of the signal that can be converted by the A / D converter 23b may not be obtained. On the other hand, in order to change the amplification factor in the signal output from one linear CCD sensor 15 for each color of the LED 11, it is necessary to provide each amplifier corresponding to the color of the light, and the cost increases. Control becomes complicated. For this reason, here, the amplification factor is adjusted by a signal output from the linear CCD sensor 15 by the light of a predetermined color, and the light emission time of the LED 11 of the other color is changed to input to the A / D converter 23b. Adjust the value of the output signal.

  The LEDs 11r, 11g, and 11b emit light by driving the light source driver 22 under the control of the CPU 54. The CPU 54 controls to start light emission based on a charge readout pulse as an acquisition signal for periodically acquiring light amount information by the linear CCD sensor 15 and to turn off after the set light emission time has elapsed. At this time, the light emission start timing of each LED 11 does not necessarily coincide with the rise or fall of the charge readout pulse, and the light emission start timing is set by the CPU 54 so as to start light emission after a predetermined time from the rise and fall. It is also possible to control.

  The adjustment of the value of the signal input to the A / D converter 23b is such that the maximum value of the signal from the linear CCD sensor 15 by the light of each color is the value of the signal that can be converted by the A / D converter 23b. Since the maximum value is adjusted, the white original is read so that the signal of the maximum value can be obtained from the linear CCD sensor 15 by the light of each color.

FIG. 8 is a flowchart showing an example of a method for adjusting the output of the linear CCD sensor 15.
Adjustment of the output of the linear CCD sensor 15 is performed before reading the document 5 placed on the document table glass 7. When receiving the reading start command, the color scanner 10 moves the carriage 16 to a position outside the document placement area as described above. At this time, a position where the carriage 16 moves is provided with a reference white document vertically above the linear CCD sensor 15, that is, in the reading area. At this time, the white original is provided such that the distance between the white original and the linear CCD sensor 15 is the same as the distance between the linear CCD sensor 15 and the original 5 placed on the original table glass 7 and to be read. . Similarly to the original 5 to be read, if the white original is provided between the linear CCD sensor 15 and the original table glass 7, the white original can be adjusted under the same conditions as when the original 5 is read. It is possible to make an accurate adjustment.

  When the carriage 16 is moved so that the linear CCD sensor 15 is positioned vertically below the white document, the three color LEDs of the light source unit 18 are switched under the control of the CPU 54 and sequentially lighted for the same light emission time. The value of the signal from the CCD sensor 15 is acquired (S202). At this time, the carriage 16 may be in a stopped state. However, the carriage 16 is accelerated to a predetermined speed for reading the document 5 placed on the platen glass 7 or reaches a predetermined speed to read the document 5. It may be in a state of moving so as to approach the area. As described above, when a white original is read while moving the carriage 16, it is possible to reduce the time required to read the original to be read. Further, when a white document is read while moving the carriage 16, it is possible to suppress erroneous detection of the output of the linear CCD sensor 15 that occurs when, for example, dust or the like adheres to the white document.

The acquired signal value of the linear CCD sensor 15 is temporarily stored in the memory 28 in association with the color of light (S204). At this time, the ratio of the signal values of the light of each color is also obtained and stored in the memory 28 in association with the color of the light (S206).
The signal values corresponding to the respective colors stored in the memory 28 are compared, and the light of the color having the minimum value is specified (S208).

  The LED 11 of the specified color is emitted, and the analog signal processing unit 23a performs offset adjustment for removing the offset due to the dark current from the signal output from the linear CCD sensor 15 (S210). The offset adjusted signal is amplified by the analog signal processing unit 23a, and the value of the signal of the linear CCD sensor 15 by the light of the specified color becomes the maximum value of the signal that can be converted by the A / D converter 23b. Thus, the amplification factor is adjusted (S212). This adjustment is performed by the CPU 54 executing a predetermined computer program stored in the ROM of the memory 28. By this adjustment, an amplification factor when the analog signal processing unit 23a amplifies is set, and the signal value is minimized. The adjustment for the light to be completed is completed. Here, when an offset occurs in the obtained signal by adjusting the amplification factor, the amplification factor may be adjusted as necessary after the offset adjustment is performed again.

  Next, the value of the signal that can be converted by the A / D converter 23b after the signal has been amplified at a set amplification factor with the light of other colors except the light of the color having the minimum signal value. The light emission time of the LED 11 that emits light of other colors is determined so as to be the maximum value (S214).

  Since the set amplification factor is set to correspond to the light having the minimum output, if the output of the linear CCD sensor 15 by light of another color is amplified with the same amplification factor, it is natural that A The value of the signal input to the / D converter 23b is too large to be properly converted. For this reason, in order to optimize the value of the signal input to the A / D converter 23b, the light emission time of the LED 11 that emits light of other colors, the signal value of the linear CCD sensor 15 stored in the memory 28, and the color of each color It is determined based on the ratio of signal values corresponding to light.

  By the way, the linear CCD sensor 15 accumulates charges with time according to the intensity of light irradiated to each light receiving element and outputs it as a signal. Based on the idea that the value of the output signal changes approximately in proportion to the irradiation time if the intensity of the irradiated light is constant, the light emission time of the LED 11 that emits light of other colors is calculated. decide.

For example, the maximum value of the signal that can be converted by the A / D converter 23b is 1200 mV, and when the LEDs 11r, 11g, and 11b of each color are turned on for 20 nsec, the signal value of the linear CCD sensor 15 is Assume that red is 300 mV, green is 400 mV, and blue is 600 mV. At this time, the output ratio of each color is red: green: blue = 3: 4: 6, and the value of this signal and the ratio thereof are stored in the memory 28 (S206).
Since the color with the smallest output is red, the amplification factor by the analog signal processing unit 23a is set to “4” so that the value of the signal of red light is 1200 mV (S212).

Referring to the ratio stored in the memory 28, the value after amplification of the signal with green light is 4/3 times the value after amplification of the signal with red light, and after amplification of the signal with blue light. It is recognized that the value is twice the value after amplification of the signal with red light. For this reason, the light emission time of the LED 11g emitting green light is
20nsec x 3/4 = 15nsec
The emission time of the LED 11b emitting blue light is determined as follows:
20nsec x 1/2 = 10nsec
(S214).

  When the light emission times of the LEDs 11r, 11g, and 11b of the respective colors are determined, the linear CCD sensor 15 by each light is switched while the three color LEDs are switched under the vertical direction of the white original and sequentially lighted at the determined light emission time. The light emission time of the LED 11 is finely adjusted with a higher resolution adjustment width so as to obtain 1200 mV (S216). In this fine adjustment, the three color LEDs are switched to emit light sequentially, and the output value when the signal value of the linear CCD sensor 15 by the light of each color is converted into digital image data by the AFE unit 23 is detected and 1200 mV is detected. Until the value corresponding to the value in the predetermined range in the vicinity is obtained, the light emission time is adjusted by the control of the CPU 54 while sequentially switching the LEDs to emit light, and the process ends when an appropriate value is obtained.

  According to such a color scanner 10, before reading the document 5, the signal value of the linear CCD sensor 15 when the three colors of light are emitted toward the white document at the same light emission time is acquired in advance. Of the acquired signal values, the signal value after amplification by the light of the color that minimizes the signal value is first set to the upper limit value that can be converted by the A / D converter 23b. Since the amplification factor is adjusted in such a manner, it is not necessary to repeatedly perform adjustments such as adjusting the signal value of the linear CCD sensor 15 by the light of each color while changing the amplification factor due to insufficient light amount. For this reason, it is possible to shorten the time spent for adjustment and to adjust the output value from the linear CCD sensor 15 in a short time.

  In addition, since an LED with low luminance is used as the light source, the color of the light to be adjusted first is set to the color that minimizes the value of the signal when each of a plurality of colors of light is emitted in the same emission time. Is particularly effective in reducing the adjustment time.

  Further, only the first color light is adjusted without adjusting the signal value of the linear CCD sensor 15 with respect to all the color lights, and the light of the other colors is emitted and output first. Since it is determined based on the ratio of signals, it can be adjusted to an appropriate value in a short time. For this reason, it is possible to shorten the adjustment time as compared with the case where light is emitted for each color and the light is sequentially adjusted.

=== Acquisition timing of linear CCD sensor and light emission timing of LED ===
As described above, the light source unit 8 emits light of three colors of red (R), green (G), and blue (B) sequentially while moving the carriage 16, and the linear CCD sensor 15 emits light amount information. Is read at a predetermined cycle, and an image corresponding to the distance moved by the carriage 16 during one cycle is captured as light amount information for one line corresponding to the output image. For this reason, even if the light amount information is for one line, the signal output from the linear CCD sensor 15 by the light of the three colors red (R), green (G), and blue (B) has the reading position of the document. Slightly different. In order to suppress the difference in reading position in the light amount information for one line as much as possible, the light emission timing of the LED 11 with respect to the capture timing of the linear CCD sensor 15 is set.
FIG. 9 is a timing chart for explaining the capture period of the linear CCD sensor and the light emission start timing of the LED.

The capture timing of the linear CCD sensor 15 is set in advance at a predetermined cycle (capture cycle).
This take-in cycle is divided into a charge period for storing the information of the light irradiated on the linear CCD sensor 15 and a transfer period for transferring the stored information to the AFE unit 23, and the charge readout sent at a constant cycle. Separated by pulses. The charge period is a period from the fall of the charge read pulse to the rise of the next charge read pulse, and the transfer period is a period from the rise of the charge read pulse to the fall. That is, in this example, the charge period is the charge period when the charge readout pulse is at the low level, and the transfer period is when the charge read pulse is at the high level.

  The three-color LEDs 11r, 11g, and 11b used as the light sources have a large variation in the amount of light between the colors, so it is necessary to adjust the amount of each light. To adjust this variation, the light emission time of the LED 11 of each color is adjusted. Is as described above. For this reason, the light emission time of each color LED 11 is set shorter than the charge period of the linear CCD sensor 15.

  The interval at which the carriage 16 moves to read one line of document is defined as one pixel interval. One pixel section is from the fall of a certain charge readout pulse to the fall of the third charge readout pulse. That is, one charge section includes three charge readout pulses, and until the fall of the first charge readout pulse, an R capture period in which light amount information by red (R) light is captured, G capture period in which light quantity information by green (G) light is captured until the fall of the charge readout pulse, and light quantity information by blue (B) light is captured until the fall of the third charge readout pulse. It is B uptake period.

  In each charge period of the R capture period, the G capture period, and the B capture period, the light amount information by the emitted LED is transferred to the AFE unit 23 in each transfer period. That is, only information while the LED 11 emits light is captured and transferred to the AFE unit 23 during each charging period. For this reason, the LED of each color is set so that the light emission time of the LED 11 of each color is closest within one pixel section, that is, the time from the start of light emission of the red LED to the end of light emission of the blue LED is the shortest. Set the flash timing.

  Since the charge readout pulse is generated at a constant period, this interval cannot be changed. In addition, one capture period always requires three capture periods. For this reason, it sets so that the light emission time of red LED 11r and the light emission time of blue LED may approach in the G taking period which is the middle of one pixel area. That is, the light emission time of the red LED 11r ends immediately before the transfer period in the R capture period (immediately before the first capture signal), and immediately after the transfer period in the G capture period (second capture signal). The light emission time of the blue LED 11b starts immediately after. At this time, when adjusting the light emission time of the red LED 11r in the adjustment of the output signal of the linear CCD sensor described above, the light emission start timing of the red LED 11r is changed and the light emission time of the blue LED 11b is adjusted. If necessary, it is adjusted by changing the light emission time of the blue LED 11b.

  In this way, by setting the light emission time of the red LED 11r and the light emission time of the blue LED 11b, the timing of emitting the light of the three colors is made closest, and the linear CCD sensor 15 obtains the light amount information of each color during the carriage. It is possible to reduce the distance that 16 moves. Therefore, since the light quantity information of the three colors of light corresponding to one pixel is read in a narrow range of the original, the original and the original due to the difference in the reading timing of each color data generated when the emission color of the LED 11 is changed and read. It is possible to suppress the color difference from the image data.

  That is, since the color scanner 10 can arbitrarily set the light emission timing of each color LED 11, in order to capture the light amount information of the three colors of light corresponding to one pixel, the timing interval at which the LED 11 emits light in each color is set. A color scanner that can be narrowed and can suppress the color difference between the original and the image data is realized.

  Further, when the light emission time of the green LED 11g is set at the center in the G capture period, the interval between the light emission time of the red LED 11r and the light emission time of the green LED 11g and the interval between the light emission time of the green LED 11g and the light emission time of the blue LED 11b are as follows. Almost equal. Accordingly, since only the light emission time of the red LED 11r or the blue LED 11b is not emitted at a time interval in one pixel section, the color of the image due to the read signal is less likely to be biased, and the original and the image data are further reduced. It is possible to suppress the difference in color with the. In addition, since the light amount information of each color light is captured at a position close to the center of one pixel section to be read, the information on the pixel to be read can be accurately read from the light amount information captured at the biased position of the pixel. Is possible.

  Further, by emitting green light with the highest human sensitivity in the middle of one pixel section, the original at the center is read with light of the most sensitive color at the moving distance of the carriage 16. become. Therefore, it is possible to read information more suitable for human eyes.

=== Other Embodiments ===
The present invention is not limited to the above-described embodiment, and can be implemented in various modes without departing from the gist thereof. For example, the following modifications are possible.

  In the above embodiment, an example in which the linear CCD sensor 15 is used as the image sensor has been described. However, a CMOS sensor in which light receiving elements are arranged in a line may be used as the image sensor.

    In the embodiment, the light source includes the LED 11 having the red LED 11r, the green LED 11g, and the blue LED 11b, the light guide 12 and the light guide cover 13, and one end face 12a of the light guide 12. Although the light emitted from the LEDs 11r, 11g, and 11b of the respective colors is incident on the light guide 12 to irradiate the original, the plurality of LEDs 1r, 11g, and 11b are arranged in a line. The arranged LED array may be used as a light source. In this case, it is possible to obtain a high amount of light, but it is necessary to control the variation of each LED, and the cost may increase because many LEDs are used. For this reason, the light source unit 8 of the above embodiment is superior. In addition, although the light emitted from the light source has three colors of R, G, and B, the present invention is not limited to this, and other colors of light may be used as necessary.

  Moreover, although the example which arrange | positions LED11 only to the one end surface 12a side of an element arrangement direction was shown in the said Example, you may arrange | position some LED to the other end surface 12d side. That is, the LEDs 11 may be disposed at both ends of the light guide 12 in the longitudinal direction Y. Specifically, for example, the LEDs 11r, 11g, and 11b may be arranged one by one on the end surface 12a side, and the remaining one LED 11r, 11g, and 11b may be arranged on the end surface 12d side. When the LEDs are arranged at both ends, it is possible to irradiate the document more uniformly than when the LEDs are arranged only at one of the ends.

  In addition, when the light guide 12 is formed so that the cross-sectional area of the light guide 12 becomes smaller as the distance from the end surface 12a where the LEDs 11 are arranged in the element arrangement direction, the light guide 12 is more uniform over the entire longitudinal direction of the light guide 12. It is possible to irradiate the original with light of high brightness.

  In the above embodiment, first, the signal value of the linear CCD sensor 15 by the light of each color and the ratio thereof are stored, and the value of the signal of the linear CCD sensor 15 by the color light that minimizes the signal value. As for other colors, the adjustment method for determining the light emission time based on the stored signal value of the linear CCD sensor 15 and the ratio thereof has been described. However, the present invention is not limited to this. After obtaining the signal value of the linear CCD sensor 15 by adjusting the signal value of the linear CCD sensor 15 by the light of the color that minimizes the value of the signal, the signal of the linear CCD sensor 15 by the light of other colors is adjusted. The values may be adjusted sequentially. In this case, since the value of the signal of the linear CCD sensor 15 by the light of each color is adjusted, the adjustment method of the above embodiment is superior in that the time spent for the adjustment can be shortened.

  In the above embodiment, a part of the configuration realized by hardware may be replaced by software, and conversely, a part of the configuration realized by software may be replaced by hardware.

  The present invention is applicable to a document reading and printing apparatus that receives light irradiated on a document with a sensor and converts the light into digital image data. For example, the present invention can also be applied to a facsimile machine or a copying machine provided with a document reading unit.

<<< Configuration of Document Reading System, etc. >>>
Next, an embodiment of a document reading system and a computer program, which are examples of embodiments according to the present invention, will be described with reference to the drawings.

  FIG. 9 is an explanatory diagram showing an external configuration of the document reading system. The computer system 700 includes a computer main body 702, a display device 704, a document reading device 706, an input device 708, and a data reading device 710. The display device 704 is generally a CRT (Cathode Ray Tube), a plasma display, a liquid crystal display device, or the like, but is not limited thereto. The document reading device 706 uses the color scanner described above. In this embodiment, the input device 708 uses a keyboard 708A and a mouse 708B, but is not limited thereto. In this embodiment, the data reading device 710 uses a flexible disk drive device 710A and a CD-ROM drive device 710B. However, the data reading device 710 is not limited to this. For example, an MO (Magneto Optical) disk drive device or a DVD (Digital Others such as Versatile Disk) may be used.

  FIG. 10 is a block diagram showing a configuration of the document reading system shown in FIG. An internal memory 802 such as a RAM and an external memory such as a hard disk drive unit 804 are further provided in a housing in which the computer main body 702 is housed.

  In the above description, an example has been described in which the document reading device 706 is connected to the computer main body 702, the display device 704, the input device 708, and the data reading device 710 to configure a computer system. Is not something For example, the computer system may include a computer main body 702 and a printer 706, and the printing system may not include any of the display device 704, the input device 708, and the data reading device 710.

  The computer program for controlling the color scanner in the above-described embodiment is stored in the memory on the computer main body side, and the scanner operation of the above-described embodiment is achieved by executing this computer program on the computer side. May be.

  The document reading system realized in this way is a system superior to the conventional system as a whole system.

1 is an explanatory diagram showing a schematic configuration of a color scanner as an example of a document reading apparatus according to the present invention. The block diagram which shows an example of a control part. The figure for demonstrating the structure of CIS. The side view of CIS. The schematic diagram which shows a mode that the light which LED emitted light is guided to the longitudinal direction Y of a light guide, and is radiated | emitted to a predetermined direction and irradiates a document. The figure for demonstrating a mode that an optical image is formed in a linear CCD sensor. 5 is a flowchart showing a reading operation of a color scanner. The flowchart which shows an example of the adjustment method of the output of a linear CCD sensor. The timing chart for demonstrating the taking-in period of a linear CCD sensor, and the light emission timing of LED. FIG. 2 is an explanatory diagram showing an external configuration of a document reading system. FIG. 11 is a block diagram showing a configuration of the document reading system shown in FIG. 10.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 CIS 5 Original 6 Original plate cover 7 Original plate glass 8 Light source part 10 Color scanner 11 LED 11b Blue LED
11g Green LED 11r Red LED
DESCRIPTION OF SYMBOLS 12 Light guide 12a One end surface of a light guide 12b Diffusion surface 12c Ejection surface 12d The other end surface of a light guide 13 Light guide cover 13a Opening of a light guide cover 14 Rod lens array 15 Linear CCD sensor 16 Carriage 18 Driving means 20 Regulation guide 22 Light source driver 23 AFE unit 23a Analog signal processing unit 23b A / D converter 24 Digital signal processing unit 25 Sensor driver 28 Memory
29 Guide receiving portion 50 Control portion 52 Interface 54 CPU
181 Timing belt 182 Pulley 183 Pulse motor 184 Idler pulley 700 Document reading system 702 Computer main body 704 Display device 706 Document reading device (color scanner)
708 Input device 708A Keyboard 708B Mouse 710 Data reader 710A Flexible disk drive device 710B CD-ROM drive device 802 Internal memory 804 Hard disk drive unit

Claims (9)

A light source for illuminating a document by sequentially switching light of multiple colors;
An image sensor for outputting a signal according to the amount of light received within a predetermined time,
After amplifying the signal of the image sensor by the light of the plurality of colors at the time of irradiating the original with a predetermined amplification factor, and adjusting the value of the amplified signal to be a predetermined value,
An original that emits light from the light source, illuminates the original, outputs the signal for each color from the image sensor, and reads the original by associating the value of the signal by a plurality of colors of light output in succession with one pixel. In the reading device,
During the adjustment, among the signal values when light of a plurality of colors is emitted at the same light emission time, the value of the amplified signal by the light of the color that minimizes the signal value is And an original reading apparatus that adjusts to a predetermined value. The document reading device according to claim 1,
The document reading apparatus according to claim 1, wherein the adjustment is performed by adjusting the amplification factor so that a value of the amplified signal by a light of a color having a minimum value of the signal becomes a predetermined value. In the document reading device according to claim 1 or 2,
Based on the ratio of the signal value of the image sensor by the light of each color when emitting light of a plurality of colors in the same light emission time, other colors excluding the light of the color having the minimum signal value An original reading apparatus, wherein the light emission times of the other colors are determined so that a value of the amplified signal by the light of a predetermined value becomes a predetermined value. The document reading apparatus according to claim 3,
After determining the light emission time of each color light, the light of the plurality of colors is sequentially switched and emitted, and each light emission time is finely adjusted so that the value of the amplified signal by the light of each color becomes the predetermined value An original reading apparatus. The document reading device according to any one of claims 1 to 4,
The original is a white original,
The value of the signal after the amplification is converted into digital information by an analog / digital converter,
The document reading apparatus, wherein the predetermined value is an upper limit value that can be converted by the analog / digital converter. A light source for illuminating a document by sequentially switching light of multiple colors;
An image sensor for outputting a signal according to the amount of light received within a predetermined time,
After amplifying the signal of the image sensor by the light of the plurality of colors at the time of irradiating the original with a predetermined amplification factor, and adjusting the value of the amplified signal to be a predetermined value,
An original that emits light from the light source, illuminates the original, outputs the signal for each color from the image sensor, and reads the original by associating the value of the signal by a plurality of colors of light output in succession with one pixel. In the reading device,
The original is a white original,
During the adjustment, among the signal values when light of a plurality of colors is emitted at the same light emission time, the value of the amplified signal by the light of the color that minimizes the signal value is And adjusting the amplification factor to a predetermined value,
The value of the signal after the amplification is converted into digital information by an analog / digital converter,
The predetermined value is an upper limit value that can be converted by the analog-digital converter,
Based on the ratio of the signal value of the image sensor by the light of each color when emitting light of a plurality of colors in the same light emission time, other colors excluding the light of the color having the minimum signal value Each light emission time of the other color is determined so that the value of the amplified signal by the light of a predetermined value becomes a predetermined value,
After determining the light emission time of each color light, the light of the plurality of colors is sequentially switched and emitted, and each light emission time is finely adjusted so that the value of the amplified signal by the light of each color becomes the predetermined value An original reading apparatus. A light source for illuminating a document by sequentially switching light of multiple colors;
An image sensor for outputting a signal according to the amount of light received within a predetermined time,
After amplifying the signal of the image sensor by the light of the plurality of colors at the time of irradiating the original with a predetermined amplification factor, and adjusting the value of the amplified signal to be a predetermined value,
An original that emits light from the light source, illuminates the original, outputs the signal for each color from the image sensor, and reads the original by associating the value of the signal by a plurality of colors of light output in succession with one pixel. In the reader
During the adjustment, among the signal values when light of a plurality of colors is emitted at the same light emission time, the value of the amplified signal by the light of the color that minimizes the signal value is And a computer program for realizing a function of adjusting to a predetermined value. A computer body, and
A light source connected to the computer main body for emitting light by sequentially switching light of a plurality of colors;
An image sensor for outputting a signal according to the amount of light received within a predetermined time,
After amplifying the signal of the image sensor by the light of the plurality of colors at the time of irradiating the original with a predetermined amplification factor, and adjusting the value of the amplified signal to be a predetermined value,
An original that emits light from the light source, illuminates the original, outputs the signal for each color from the image sensor, and reads the original by associating the value of the signal by a plurality of colors of light output in succession with one pixel. In a document reading system having a reading device,
During the adjustment, among the signal values when light of a plurality of colors is emitted at the same light emission time, the value of the amplified signal by the light of the color that minimizes the signal value is In addition, the document reading system is adjusted so as to have a predetermined value. In order to output a signal corresponding to the amount of light received within a predetermined time by irradiating a document by emitting light of the plurality of colors in the same light emission time with a light source that sequentially switches and emits light of a plurality of colors Outputting the value of the signal by each light in the image sensor;
Amplifying the signal of the image sensor by light of a color that minimizes the value of the signal among the values of the signal by the respective lights, and a value of the signal after the amplification, First, adjusting to a predetermined value;
Illuminating the original by emitting the light source, outputting the signal for each color from the image sensor, and reading the original by associating the value of the signal by the light of a plurality of colors output in succession with one pixel. And a document reading method.

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