JP4083042B2 - Image reading apparatus and image reading method - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an image reading apparatus and method for irradiating a document with light and photoelectrically converting reflected light from the document to obtain image data of the document, and in particular, reading a document image including a glossy image such as gold or silver. The present invention relates to an image reading apparatus and method suitable for the above.
[0002]
[Prior art]
Generally, an image reading apparatus is configured to generate image data (convert to electronic data) of a document by irradiating the document with light from a predetermined light source and guiding reflected light from the document to a photoelectric conversion element. Yes.
FIG. 8 is a diagram schematically showing the direction of reflection of light irradiated on a general paper document by an arrow line. As shown in FIG. 8A (cited from Non-Patent Document 1), since the surface of the paper document has minute irregularities, when the surface is irradiated with light, the reflected light is reflected in FIG. As shown in Patent Document 2, the light is diffusely reflected in various directions (diffuse reflected light) and hardly specularly reflected (reflected in a direction symmetrical to the incident angle). Here, as the surface state (paper quality) of a paper document becomes more glossy as in a photograph or the like, the proportion of reflected light that is regularly reflected increases. In other words, the ratio of the reflected light from the paper document to the regular reflected light varies greatly depending on the surface state of the document.
For this reason, in conventional image reading devices, photoelectric conversion elements are used so that image reading results do not vary greatly due to differences in surface conditions (glossiness, flatness, surface roughness) between documents. The reflected light guided to the light is configured to be reflected light of only the diffuse reflection component (diffuse reflected light). For example, there is a configuration in which light is emitted from a direction of about 45 ° with respect to a direction perpendicular to the document surface, and reflected light in a direction substantially perpendicular to the document surface is guided to a photoelectric conversion element.
[0003]
FIG. 7 is a sectional view showing a schematic configuration of such a conventional general image reading device Z. As shown in FIG.
As shown in FIG. 7, the conventional image reading device Z has a light irradiated in a predetermined irradiation direction A from a light source 20 such as a fluorescent lamp (the direction of an angle α0 with respect to the normal direction of the document surface (for example, α0 = 45 °)), the original 10 placed on the platen glass 11 is illuminated. Of the reflected light, diffuse reflected light in the predetermined reflection direction C (in FIG. 7, diffuse reflected light in a direction perpendicular to the original) is reflected by the first mirror 31, the second mirror 32, and the third mirror 33. Then, the light is guided and input to the CCD unit 50 by the imaging lens 40. The CCD unit 50 includes a color line sensor 51 including a photoelectric conversion element (see FIG. 2), and forms an image of a document image from light (diffuse reflected light) input to the color line sensor 51. Further, the CCD unit 50 outputs an analog signal color-separated by the three color line sensors R, G, and B, and converts the output into a digital signal by the AD conversion unit 52 (see FIG. 2). , Output as image data.
In such a configuration, the reflected light in the regular reflection direction B (regularly reflected light (reflected light in a direction in which the irradiation angle α0 and the reflection angle α1 are symmetric)) is hardly included. Therefore, as long as a general paper document is used, even if the surface state of each document is different, the image reading result does not vary greatly, and the color of the document image can be read correctly.
On the other hand, Japanese Patent Application Laid-Open No. H10-228707 discloses that image data having a luminance exceeding the white level of a reference white plate is processed as image data of a fluorescent marker image or gold-silver color image.
[0004]
[Patent Document 1]
Japanese Patent Laid-Open No. 10-271347
[Non-Patent Document 1]
Japanese Society of Color Science “New Color Chemistry Handbook (Second Edition)” P.714 Figure 18.2
[Non-Patent Document 2]
Trikeps “Color Image Scanner Design Technology” P.43 Figure 42
[0005]
[Problems to be solved by the invention]
However, when the original image includes a very high gloss image such as an image having a metallic color such as gold or silver, most of the irradiation light is reflected as specular reflection light in the high gloss portion. In addition, the amount of diffusely reflected light is significantly reduced.
FIG. 9A (cited from Non-Patent Document 2) is a diagram schematically showing the light reflection direction by an arrow line when the surface of the irradiated object is mirror-like. When the surface of the object to be irradiated is mirror-like, as shown in FIG. 9A, all of the irradiated light is regularly reflected (regularly reflected light), and no diffuse reflection occurs. Further, even if the surface of the irradiated object is not mirror-like, if a metallic color (gold color, silver color, etc.) is printed, as shown in FIG. 9B (cited from Non-Patent Document 1). In addition, although there is some scattering, reflected light that is almost regular reflection is formed, and the ratio of diffuse reflection is significantly reduced.
For this reason, when the above-described highly glossy original image is read by a conventional image reading device, a dark (blackish) image data is generated due to a decrease in the amount of reflected light input to the photoelectric conversion element. As a result, the original correct image data cannot be obtained.
[0006]
10A shows an original on which patch images of each color of red R, green G, blue B, white W, gray GY, black BL, gold GOLD, and silver SILVER are formed, and FIG. 10B shows FIG. 10A shows an output image of the image data obtained by reading the diffuse reflection light of the original image of FIG. 10A, FIG. 10C shows the regular reflection light B of the original image of FIG. It is the figure which represented typically the output image of the image data obtained by narrowing down and reading.
As shown in FIG. 10B, when image data is generated from the diffusely reflected light, the original image is used for the commonly used colors (R, G, B, W, GY, BL). Can be obtained, but image data of a dark (blackish) image is generated for the metal color (GOLD, SILVER), and the original image cannot be read correctly.
On the other hand, when image data is generated from the specularly reflected light with a sufficiently reduced amount of light, as shown in FIG. 10C, for the metal colors (GOLD, SILVER), image data in which the original image is correctly reproduced is obtained. Although it can be obtained, for general colors other than black (R, G, B, W, GY), image data of a dark (blackish) image is generated, and the original image cannot be read correctly. Here, although not shown in the drawing, if the general color (R, G, B, W, GY, BL) is read correctly by loosening the aperture of the light amount of the regular reflection light, the metal color ( For GOLD, SILVER), the light receiving luminance at the CCD unit 50 overflows, resulting in image data of a pure white image.
[0007]
Of course, in a current general image output device that displays image data or records on recording paper or the like, it may be difficult to output a metallic color such as gold or silver as it is, but even in such a case, at least It can be said that the correct reading of image data is that image data is obtained as a yellowish color for gold and a grayish color for silver.
In particular, as digital devices such as personal computers, printers, and scanners (image readers) have become widespread in recent years, and the image data to be handled has diversified, such as creating New Year's cards and cards that contain gold and silver characters and images, the above problems Has become more apparent. For example, since a general user does not understand the principle of image reading, the above phenomenon may be misunderstood as being caused by a failure of the apparatus.
In addition, when generating image data from diffusely reflected light of a document, it is considered that the highly glossy document image cannot be read more and more with the technique of Patent Document 1 that processes high-luminance data as gold-silver (metal color) or the like. .
Accordingly, the present invention has been made in view of the above circumstances, and the object of the present invention is to provide an original document even when a highly glossy image such as a metal color image exists in the original image. An object of the present invention is to provide an image reading apparatus and method capable of reading correct image data in accordance with image characteristics.
[0008]
[Means for Solving the Problems]
  In order to achieve the above object, the present invention comprises photoelectric conversion means for generating image data by irradiating a document with light, inputting reflected light reflected from the document in a predetermined reflection direction, and performing photoelectric conversion. In the image reading deviceThe reflected light mainly becomes diffusely reflected light.A first irradiation direction andThe reflected light is mainly regular reflected light.From each of the second irradiation directionAgainst the manuscriptFirst and second light sources for irradiating light, reflection-side light guide means for guiding the reflected light to the photoelectric conversion means,For each of the corresponding positions based on a comparison of the data of the positions corresponding to each other in the two image data generated by inputting the reflected light with respect to the light of each of the first and second light sources to the photoelectric conversion means. Image data synthesizing means for synthesizing the image data of the original by selecting any one of the data;It is comprised as an image reader characterized by comprising.
  As a result, either reflected light for the light in the first irradiation direction or reflected light for the light in the second irradiation direction is selected.SelectImage data corresponding to the characteristics of the original image can be obtained.
[0009]
  For example, any of the first and second light sourcesFromIf an irradiation direction switching means for switching whether to irradiate the document with light is provided, two image data with different light irradiation directions can be obtained from one document, and these can be obtained according to the characteristics of the document image. Correct image data can be obtained by selecting or combining one of the two image data.
[0010]
  In additionThe first irradiation direction is a direction in which the reflected light is mainly diffusely reflected light, and the second irradiation direction is a direction in which the reflected light is mainly regular reflected light.For,An image of a general color with relatively low gloss that mainly reflects light as diffusely reflected light, and a very glossy metal color that has the property of mainly reflecting light as regular reflected light. Image data corresponding to each of the high imagesTObtainable.
[0011]
Here, when the glossiness of the original image becomes very high as in the case of a metal color image, most of the irradiation light is reflected in the regular reflection direction. Therefore, when the intensity of the irradiation light on the original is equal, the diffuse reflection The intensity of regular reflection light is higher than the intensity of light. When these are photoelectrically converted by the common photoelectric conversion means, it is necessary to reduce the resolution of photoelectric conversion so that one of them overflows or does not cause overflow.
In order to solve this problem, the intensity of light applied to the original in the second irradiation direction (substantially regular reflection direction) is such that the original in the first irradiation direction (diffuse reflection direction) is irradiated. It can be considered that it is made weaker than the intensity of light.
For example, an optical path length from the light source on the second irradiation direction side to the original is longer than an optical path length from the light source on the first irradiation direction side to the original. Thereby, the intensity of irradiation light is inversely proportional to the square of the optical path length.
It is also conceivable to include a second light amount adjusting means capable of adjusting the amount of light passing through the optical path on the second irradiation direction side. Further, if the first light amount adjusting means capable of adjusting the amount of light passing through the optical path on the first irradiation direction side is provided, the irradiation light from each of the first and second irradiation directions can be adjusted. Strength can be adjusted more flexibly.
[0012]
  Further, the first light amount adjusting means and the first light quantity adjusting means and the image data generated by the photoelectric converting means.BeforeOf the second light quantity adjusting meansOne or bothIf the light quantity automatic adjusting means for adjusting the amount of light passing is provided, the intensity of the irradiated light can be easily adjusted.
[0013]
Further, the first and second light quantity adjusting means may also serve as the irradiation direction switching means. For example, the number of components can be reduced by using a liquid crystal shutter that can perform both light amount adjustment (light passage amount adjustment) and shuttering (light blocking).
[0014]
If the predetermined reflection direction is an oblique direction with respect to the document surface, the second irradiation direction and the second irradiation direction are set when the second irradiation direction is set so that the reflection direction becomes a substantially regular reflection direction. Since the reflection direction is symmetric with respect to the direction perpendicular to the document surface, the second light source and the reflection-side light guide means do not interfere with the irradiation light in the second irradiation direction and the path of the reflected light. Can be arranged as follows.
Further, if the reflection side light guide means includes a magic mirror, and the second light source passes light through the magic mirror and irradiates the original from the second irradiation direction, The reflection direction can be a direction perpendicular to the document surface. Further, in this case, since the light in the second irradiation direction attenuates when passing through the magic mirror, it is suitable when it is desired to weaken the irradiation light in that direction.
[0015]
The irradiation direction switching means may be one that switches the irradiation direction each time the light source is moved to scan the entire image reading range of the document. For example, if the irradiation direction is switched between the forward path and the backward path of the scanning, two image data with different light irradiation directions can be obtained by reciprocating the scanning of the document once.
On the other hand, it is also conceivable that the irradiation direction switching means switches the irradiation direction for each predetermined reading unit while moving the first and second light sources and scanning the entire image reading range of the document.
According to this, two image data can be obtained by scanning the document once (one-way scanning). This can be realized by using an LED or the like capable of high-speed ON / OFF switching as the first and second light sources. Here, the reading unit may be, for example, one line in the sub-scanning direction perpendicular to the main scanning direction in which each light source is moved.
[0016]
Further, if the wavelengths of the first and second light sources are the same, a filter or the like for correcting the range of the used wavelength for each light source is used, or correction based on the difference in the used wavelength of the read image data is performed. There is no need to do it.
[0017]
  According to the invention, saidImage data synthesis meansByAccording to the characteristics of the original image, it is possible to obtain image data in which the original image is correctly reproduced..
[0018]
  The present invention may also be understood as an image reading method for synthesizing document image data from two image data obtained by irradiating a document with light from two light sources.
  That is, the original is irradiated with light, and the reflected light reflected from the original in a predetermined reflection direction is reflected.By photoelectric conversion meansIn the image reading method for obtaining image data of a document by photoelectric conversion, each of the light from the first and second light sources is divided into a first irradiation direction in which the reflected light is mainly diffuse reflected light, and the reflected light is mainly used. Are irradiated from each direction with the second irradiation direction to be specularly reflected light, and the reflected light with respect to the irradiated light in each direction isBy the photoelectric conversion meansTwo image data after photoelectric conversionBy selecting one of the data for each corresponding position based on the comparison of the data of the positions corresponding to each other inAn image reading method for combining image data of the original.
[0019]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, embodiments and examples of the present invention will be described with reference to the accompanying drawings so that the present invention can be understood. It should be noted that the following embodiments and examples are examples embodying the present invention, and do not limit the technical scope of the present invention.
FIG. 1 is a sectional view showing a schematic configuration of a main part of the image reading apparatus X according to the embodiment of the present invention, and FIG. 2 is a schematic view of the periphery of the control unit of the image reading apparatus X according to the embodiment of the present invention. 3 is a block diagram showing the configuration, FIG. 3 is a flowchart showing a procedure of image reading processing in the image reading apparatus X according to the embodiment of the present invention, and FIG. 4 is a diagram of image data in the image reading apparatus X according to the embodiment of the present invention. FIG. 5 is a cross-sectional view illustrating a schematic configuration of a main part of the image reading apparatus X1 according to the first embodiment of the present invention, and FIG. 6 illustrates a second embodiment of the present invention. FIG. 7 is a cross-sectional view showing a schematic configuration of a main part of the image reading apparatus X2, FIG. 7 is a diagram showing a schematic configuration of a main part of a conventional general image reading apparatus Z, and FIG. 9 schematically showing the reflected direction of the reflected light, FIG. FIG. 10 schematically shows a reflection direction of light irradiated on a mirror-like surface and a metal color image, and FIG. 10 shows a document image image on which a patch image of a plurality of colors is formed, its diffuse reflection light, and normal light. It is the figure which represented typically the output image of the image data obtained by reading reflected light.
[0020]
First, the configuration of the image reading apparatus X according to the embodiment of the present invention will be described with reference to FIGS. 1 and 2.
In the present image reading apparatus X, the light applied to the document 10 placed on the platen glass 11 is reflected in a predetermined reflection direction C (a direction at a minute angle α3 (> 0) from the direction perpendicular to the document surface, that is, the document. A first mirror 31, a second mirror 32, and a third mirror 33 (an example of the reflection side light guide means) for guiding reflected light reflected obliquely with respect to the surface) to a predetermined position (position of the CCD unit 50); An imaging lens 40 that condenses the light guided by each of these mirrors 31 to 33 and a CCD (Charge Coupled Device) unit 50 that inputs the light condensed by the lens 40 are provided.
The light input to the CCD unit by the imaging lens 40 is imaged on a color line sensor 51 built in the CCD unit 50 (an example of photoelectric conversion means). The color line sensor 51 converts (photoelectrically converts) the light from the imaging lens 40 into analog electrical signals of R, G, and B colors. The analog electric signal is converted into digital image data by the AD converter 52.
The configuration up to this point is the same as that of the conventional general configuration described above except that the first mirror 31 is arranged so as to guide the diffuse reflected light in the oblique direction from the direction perpendicular to the surface of the document 10 by a minute angle α3. This is the same as the typical image reading apparatus Z.
Further, the image reading apparatus X includes two light sources, a first light source 21 and a second light source 22 (exposure lamps such as a halogen lamp, a xenon lamp, a fluorescent lamp, and an LED) as light sources for irradiating the document 10 with light. And a light amount adjusting means 23 provided in the middle of the optical path from one second light source 22 to the document 10.
The first light source 21 irradiates light from a predetermined first irradiation direction A1 (direction perpendicular to the original surface at an angle α0) with respect to the original 10, and the second light source 22 Irradiates the document 10 with light from a different second irradiation direction A2 (direction perpendicular to the document surface at an angle α2). The light sources 21 and 22 are the same type of light source, and the wavelengths of the lights are the same.
The light amount adjusting means 23 is composed of, for example, a liquid crystal shutter or the like, and adjusts the amount of light (irradiation light) passing through the optical path in the second irradiation direction A2 (that is, the intensity of irradiation light on the document in the irradiation direction A2). Adjust the thickness). Here, it is used to reduce the amount of irradiation light in the second irradiation direction A2 rather than irradiation light in the first irradiation direction A1. Here, if the same light quantity adjusting means is provided also on the first light source 21 side, the intensity of the irradiation light from each of the first and second irradiation directions A1 and A2 can be adjusted more flexibly.
The light sources 21, 22, the light amount adjusting means 23 and the first mirror 31 are unitized to form a first scanning unit 30a, and the second and third mirrors 32, 33 are unitized to form a second scanning unit. 30b, and each scanning unit 30a, 30b is movable along a document 10 (that is, along the platen glass 11) in a predetermined main scanning direction (left and right direction in FIG. 5). It is configured.
[0021]
The first irradiation direction A1 is such that the reflected light in the reflection direction C of the light in the direction A1 becomes diffuse reflected light, that is, the regular reflection direction B of the light in the first irradiation direction A1 and the The reflection direction C is set to be relatively different (for example, about 40 ° different). As a result, when the original 10 is irradiated with light from the first irradiation direction A1, only the diffuse reflected light is mainly guided to the CCD unit 50 by the mirrors 31 to 33.
On the other hand, the angle α2 in the first irradiation direction A1 and the angle in the reflection direction C are substantially symmetrical (α2≈α3) with respect to the direction perpendicular to the surface of the document 10. Thereby, when the original 10 is irradiated with light from the second irradiation direction A2, the specularly reflected light is mainly guided to the CCD unit 50 by the mirrors 31 to 33.
[0022]
The image reading apparatus X includes an optical system moving method in which the original 10 is stopped on the platen glass 11 and the first and second scanning units 30a and 30b are moved to read an image, and the first and second scanning units. The scanning unit 30a, 30b can be stopped at a predetermined position, and the original image can be read by any method of the original moving method in which the original image is read while the original 10 is conveyed. Here, the optical system moving method will be described.
In the optical system moving method, the first scanning unit 30 a illuminates the document 10 while moving at a constant speed V in parallel along the platen glass 11 below the platen glass 11. Then, the reflected light reflected from the original 10 in the reflection direction C follows (interlocks with) the first scanning unit 30a and moves at a speed of V / 2 by the second scanning unit 30b. Led to. The second scanning unit 30b is configured to be interlocked with the first scanning unit 30a by a link mechanism using a wire or the like.
The image reading apparatus X is configured to fix the imaging lens 40 and the CCD unit 50, but is not limited to this, for example, the light sources 21, 22, the imaging lens 40, and the CCD unit. A configuration may be adopted in which a reduction reading optical system or unity reading optical system unit configured by unitizing 50 is scanned at a predetermined speed V.
[0023]
FIG. 2 is a block diagram illustrating a schematic configuration around the control unit of the image reading apparatus X.
The image reading apparatus X controls the driving motor 62 that drives the first scanning unit 20a, controls the amount of light passing through the light amount adjusting means 23 in the first scanning unit 20a, and turns on the light sources 21 and 22. A control unit 60 (an example of the automatic light amount adjusting unit) that controls the entire image reading apparatus X such as ON / OFF control.
The control unit 60 includes a CPU, ROM, RAM, and the like (not shown), and performs various controls by executing predetermined programs.
Further, the image reading apparatus X includes an operation unit 63 such as a touch panel, the first scanning unit 20a, a position detection unit 61 that is a sensor for detecting the position of the first scanning unit 20a, the drive motor 62, and the CCD unit. 52. An image processing unit 65 (an example of the image data synthesizing unit) that temporarily stores the image data generated by the CCD unit 50 in the image memory 66 and performs various image processing by a predetermined processing unit 67, the image processing unit An output unit 64 that outputs the processed image data to an image forming apparatus, an external memory, or the like is provided by 65, and these are controlled by the control unit 60.
[0024]
Next, the procedure of image reading processing in the image reading apparatus X will be described with reference to the flowchart of FIG. In the following, S1, S2,... Represent processing procedure (step) numbers. The processing shown in FIG. 3 is started when a predetermined reading start operation is performed from the operation unit 63 in a state where the document 10 is placed on the platen glass 11 by the user. The image reading process is controlled by the control unit 60.
First, when the reading start operation is performed, the light of the first light source 20 is irradiated (illuminated) on the document 10 from the first irradiation direction A1, and the entire image reading range of the document 10 set in advance is set. The scanning of the first scanning unit 30a is started (by this, the second scanning unit 30b is also interlocked), and the original image is read by the CCD unit 50 (S1). Here, the light irradiation direction is selected by turning on (turning on) the first light source 21 and turning off (turning off) the second light source 22. Of course, each optical path from the light sources 21 and 22 to the document 10 may be provided with a means for switching light passing / blocking, such as a mechanical simple shutter using movable blades, for example. . The image reading range is set in advance from the operation unit 63, or is set in advance by a known automatic document size detection function.
Along with scanning by the first scanning unit 30a, the CCD unit 50 performs photoelectric conversion by the color line sensor 51 and generation of image data by the A / D conversion unit 52 (S2). Is stored in the image memory 66 of the image processing unit 65 (S3). Thus, image data obtained by light irradiation in the first irradiation direction A1 by the first light source 21, that is, image data obtained from diffusely reflected light is hereinafter referred to as first image data. Further, R, G, and B image data in the first image data are represented by (r1, g1, b1).
[0025]
As described above, when the reading (generation) of the first image data for the entire image reading range of the document 10 is completed, the light from the second light source 22 is then transmitted from the second irradiation direction A2 to the document. The first scanning unit 30a starts scanning the entire image reading range of the document 10 while irradiating (illuminating) the document 10 (the second scanning unit 30b is also interlocked with this), and the CCD unit 50 causes the document image to be scanned. Is read (S4). Here, the selection of the light irradiation direction is performed by turning on the second light source 22 and turning off the first light source 21. Here, the light amount adjusting means 23 has a light passage amount so that the output of the color line sensor 51 does not overflow even when the regular reflection light (relatively strong light) is input to the CCD unit 50. It is adjusted (set) to be low enough. For example, the intensity (light quantity) of the irradiation light on the document 10 is a ratio of about 1: (1/10) to (1/20) between the first irradiation direction A1 and the second irradiation direction A2. Is set to be
It is also conceivable to adjust the emission intensity itself by adjusting the power supply to the second light source 22 or the like. However, with a general light source, it is difficult to stably adjust the light emission intensity over a wide range, so it is practical to attenuate the light intensity on the optical path as in the light amount adjusting means 23 or the like.
Then, similarly to S2 and S3 described above, image data is generated by photoelectric conversion and A / D conversion (S5), and the image data is stored in the image memory 66 of the image processing unit 65 (S6). . The image data obtained by the light irradiation in the second irradiation direction A2 by the second light source 22, that is, the image data obtained from the regular reflection light is hereinafter referred to as second image data. Further, R, G, and B image data in the second image data are represented by (r2, g2, b2).
In the above-described example, the acquisition (generation) of the first and second image data by the light irradiation in the first and second irradiation directions A1 and A2 is switched, for example, when the first image data is a document. It is conceivable that the second image data is acquired (generated) at the time of 10 forward scanning, and the second image data is acquired (generated) at the time of backward scanning. This is efficient because two image data can be obtained by one reciprocating scan with respect to the original 10. For example, the first and second light sources 21 and 22 (the first and second irradiation directions A and A2) are switched for each predetermined reading unit during scanning. It may be. According to this, two image data can be obtained by scanning the document once (one-way scanning). Here, the reading unit may be, for example, one line in the sub-scanning direction which is a direction perpendicular to the main scanning direction. However, in order to maintain the image reading speed while performing such frequent switching, it is necessary to use, as each of the light sources 21 and 22, an LED or the like that can be switched on and off at high speed.
[0026]
Next, the image processing unit 65 determines from the two image data of the first image data and the second image data whether a metal color (gold color, silver color, etc.) image portion exists (S7). ).
This determination is made, for example, by a portion in which a difference obtained by subtracting a data value of each pixel (position) of the first image data corresponding to the data value of each pixel (position) of the second image data is equal to or larger than a predetermined value. Can be determined as the image portion of the metallic color. This is because the first image data has a larger value than the second image data for a general color image in a state where the light amount is sufficiently reduced by the second light amount adjusting means 22 (ie, the second image data). In general, the data value (luminance) of the first image data is remarkably lowered in the metal color image portion. Therefore, the data value of the second image data is higher than that of the second image data. This is because it becomes larger (or the difference becomes smaller).
In S7, when it is determined that the metal color image portion exists, the image processing unit 65 causes the image data of the document 10 (document image data) based on the first image data and the second image data. (R, g, b)) are synthesized (generated), and the original image data is output by the output unit 64 (S9), and then the process is terminated.
On the other hand, if it is determined in S7 that the metal color image portion does not exist, the first image data is output by the output unit 64 (S8), and then the process ends.
[0027]
Next, an example of the method for synthesizing the document image data (r, g, b) in S9 will be described with reference to FIG.
4 (a) and 4 (b) are patch images of each color of red R, green G, blue B, white W, gray GY, black BL, gold GOLD, and silver SILVER shown in FIG. 10 (a), respectively. The first image data (r1, g1, b1) and the second image data (r2, g2, b2) for each color patch image when the image 10 of the original 10 is read by the main image reading apparatus X. ) And the data values of the original image data (r, g, b) synthesized based on them. Each data value is a value from 0 to 255 represented by 8 bits (255 is the highest luminance).
FIG. 4A shows a case where the original image data (r, g, b) is synthesized by adding both data for each pixel for the first image data and the second image data. An example is shown. For example, at the position of the green G patch image, the first image data is (5, 245, 10) (representing data values of R, G, and B, respectively), and the first image data at the position corresponding thereto is Since the two image data are (0, 11, 0), these are added to (5, 256, 10), but 255 has the highest luminance, so the original image data at the same position is (5, 255, 10).
Similarly, at the position of the gold GOLD patch image, the first image data is (3, 3, 2), and the second image data at the corresponding position is (161, 147, 90). Therefore, these are added and the original image data at the same position is (164, 150, 92).
By such addition processing, the original image data in which both the diffuse reflection light component and the specular reflection light component are taken into account is obtained. Therefore, even if the original image includes the metal color image, Therefore, normal image data can be obtained.
[0028]
On the other hand, FIG. 4B compares the data values of the pixels of the first image data and the second image data, and selects the data having the larger data value for each pixel, thereby selecting the original image data ( An example in which r, g, b) is synthesized is shown. For example, since the first image data is (5, 245, 10) and the second image data is (0, 11, 0) at the position of the green G patch image, the larger one of these data values. Is selected, and the original image data at the same position is (5,245,10).
Similarly, at the position of the gold GOLD patch image, the first image data is (3, 3, 2) and the second image data is (161, 147, 90). The larger one is selected, and the original image data at the same position is (164, 147, 90).
Since the reflected light of the metal color image portion hardly becomes the diffuse reflected light but becomes the specular reflected light, the metal color image can be added to the original image even by selecting the larger value in this way. Normal image data can be obtained even when the is included.
[0029]
By the way, since the performance of the light source 22 and the light amount adjusting means 23 varies, it is necessary to set the light passing amount of the light amount adjusting means 23 individually for each apparatus.
As a method of setting the amount of light passing through the light amount adjusting means 23, for example, a sample original including images of each color as shown in FIG. 10A is read during initial adjustment, and an actual output image is viewed. It is also possible to adjust so that an image equivalent to the original image is reproduced. However, this is troublesome and it is difficult to cope with the change with time of the emission intensity of the light source 22.
Therefore, it is conceivable that the light amount adjusting means 23 is automatically adjusted by the control unit 60 based on the image data generated by the CCD unit 50. For example, automatic adjustment by the following processing can be considered.
[0030]
First, in a predetermined adjustment mode, a sample original including an image of each color as shown in FIG. 10A is read by irradiation with light from the second light source 22. With respect to the image data generated by the reading, the image processing unit 65 determines whether or not the maximum data value falls within a predetermined upper limit value that does not overflow. Here, if it is not within the range of the upper limit value, the light passage amount (aperture) of the light amount adjusting means 23 is reset according to the maximum data value, and then the sample document is read again for processing. repeat. The adjustment ends when the maximum data value falls within the range of the upper limit value. For example, in the golden GOLD patch image portion, if there is image data (8-bit value) satisfying (r2, g2, b2) = (255, 255, 255), the maximum data value is 255, which overflows. ing. Since this is a state where the hue cannot be expressed (white), the amount of light passing through the light amount adjusting means 23 is reduced. When the range of the upper limit value is 225 to 240, for example, if (r2, g2, b2) = (230, 215, 152), the setting state of the light amount adjusting means 23 at that time is set. Store as a value.
By performing such automatic adjustment, it becomes easy to cope with variations in the performance of devices such as the light source 20 and changes with time.
[0031]
【Example】
(First embodiment)
Next, a first embodiment in which only the arrangement of the second light source 22 in the first scanning unit 20a in the image reading apparatus X is different will be described.
FIG. 5 is a cross-sectional view showing a schematic configuration of a main part of the image reading apparatus X1 according to the first embodiment of the present invention.
As shown in FIG. 5, the image reading device X1 has the same components as the image reading device X, but the optical path length from the second light source 22 to the document 10 is different from the first light source 21 to the document 10. Each of the light sources 21 and 22 is disposed so as to be longer than the optical path length up to.
Since the intensity of the irradiation light to the original 10 is inversely proportional to the square of the optical path length, the intensity of the irradiation light from the second light source 22 to the original 10 is increased by the configuration shown in FIG. It can be made sufficiently weaker than the intensity of the irradiation light from one light source 21 to the document 10. In this case, it is not necessary to perform subtle light amount adjustment by the light amount adjusting means 23, the adjustment is easy, and the adjustment accuracy of the light amount adjusting means 23 is not affected. Is stable.
For example, the intensity (light quantity) of the irradiation light on the document 10 is a ratio of about 1: (1/10) to (1/20) between the first irradiation direction A1 and the second irradiation direction A2. In order to achieve this, the ratio of both optical path lengths may be set to about 1: 3.1 to 4.4.
Such an image reading device X1 is also one embodiment of the present invention.
[0032]
(Second embodiment)
Next, an image reading apparatus X2 according to a second embodiment of the present invention will be described.
The image reading devices X and X1 cause the first mirror 31 and the second light source 22 to emit light in the second irradiation direction A2 by making the reflection direction C oblique to the document surface. In addition, they are arranged so as not to interfere with the path of the reflected light.
On the other hand, the image reading apparatus X2 adopts a coaxial illumination system in which the light from the second light source 22 is passed through the magic mirror to irradiate the original 10 with light from the second irradiation direction A2, and the second light source 22 is irradiated with light. The irradiation direction A2 and the reflection direction thereof are configured to be perpendicular to the surface of the document 10.
FIG. 6 is a cross-sectional view illustrating a schematic configuration of a main part of the image reading device X2.
As shown in FIG. 6, the image reading apparatus X2 includes a magic mirror 31 ′ instead of the first mirror 31 except that the light amount adjusting unit 23 is removed from the first scanning unit 30a of the image reading apparatus X. They are used and their arrangement is different from that of the image reading apparatus X. Others are the same as those of the image reading apparatus X.
In the image reading apparatus X2, the direction C ′ of the reflected light from the original 10 guided to the CCD unit 50 is substantially perpendicular to the surface of the original 10, as in the conventional image reading apparatus Z (FIG. 7). Thus, the magic mirror 31 ′ is arranged with its mirror surface facing the document 10. Reflected light from the original 10 reflected by the magic mirror 31 ′ is guided to the CCD unit 50 by the second and third mirrors 32 and 33.
[0033]
Further, in the image reading apparatus X2, the second irradiation direction A2 in which the light from the second light source 22 is directed substantially perpendicularly from the back surface side (surface through which light passes) of the magic mirror 31 ′ to the surface of the document 10. (An example of the irradiation side light guide means). That is, the reflection direction C ′ and the second irradiation direction A2 ′ are configured to be coaxial. Thus, when light is emitted from the second light source 22, the specularly reflected light is mainly guided to the CCD unit 50 by the magic mirror 31 ′ and the mirrors 32 and 33.
According to such a configuration, the intensity (light quantity) of the light irradiated onto the document 10 can be sufficiently reduced by increasing the light transmission loss of the light irradiated by the second light source 22 by passing through the magic mirror 31 ′. It becomes possible.
Such an image reading device X2 is also one embodiment of the present invention.
[0034]
In the above-described embodiment, whether or not to synthesize image data is switched by automatically determining the presence or absence of the metal color image portion (S7 in FIG. 3). For example, a configuration in which switching is performed by mode switching or the like by a user is also conceivable.
In the above-described embodiment, the original image data is generated by combining two image data obtained by switching (selecting) the light sources 21 and 22. For example, the light from the first light source 21 and the light from the second light source 22 may be irradiated at the same time, and the CCD unit 50 may receive the reflected light obtained by combining the reflected light of both. Good. In this case, it is necessary to set each optical path length so that a phase difference does not occur in each irradiation light in the first irradiation direction A1 and the second irradiation direction A2. As a result, it is possible to obtain image data equivalent to the original image data synthesized by the addition processing described with reference to FIG.
[0035]
【The invention's effect】
As described above, according to the present invention, correct image data can be read even when a highly glossy image such as a metal color image exists in a document image.
[Brief description of the drawings]
FIG. 1 is a cross-sectional view illustrating a schematic configuration of a main part of an image reading apparatus X according to an embodiment of the present invention.
FIG. 2 is a block diagram showing a schematic configuration around a control unit of the image reading apparatus X according to the embodiment of the present invention.
FIG. 3 is a flowchart showing a procedure of image reading processing in the image reading apparatus X according to the embodiment of the present invention.
FIG. 4 is a diagram for explaining an example of a method for synthesizing image data in the image reading apparatus X according to the embodiment of the present invention.
FIG. 5 is a cross-sectional view illustrating a schematic configuration of a main part of the image reading apparatus X1 according to the first embodiment of the present invention.
FIG. 6 is a cross-sectional view illustrating a schematic configuration of a main part of an image reading apparatus X2 according to a second embodiment of the present invention.
FIG. 7 is a diagram illustrating a schematic configuration of a main part of a conventional general image reading device Z.
FIG. 8 is a diagram schematically illustrating a reflection direction of light irradiated on a general paper document.
FIG. 9 is a diagram schematically illustrating a reflection direction of light irradiated on a mirror-like surface and a metal color image.
FIG. 10 is a diagram schematically illustrating an original image on which patch images of a plurality of colors are formed and an output image of image data obtained by reading the diffuse reflection light and regular reflection light.
[Explanation of symbols]
10 ... Original
11 ... Platen glass
21. First light source
22 ... Second light source
23. Light intensity adjusting means
31-33 ... Mirror (reflection-side light guide means)
31 '... magic mirror (reflection-side light guide means)
40: Imaging lens
50 ... CCD unit (photoelectric conversion means)
60 ... Control unit
61 ... Position detector
62 ... Drive motor
63. Operation unit
64 ... output section
65. Image processing unit (image data synthesizing means)
66. Image memory
67. Processing section
A1, A1 '... first irradiation direction
A2, A2 '... second irradiation direction
C, C '... Reflection direction

Claims (14)

In an image reading apparatus comprising photoelectric conversion means for generating image data by irradiating light on a document, inputting reflected light reflected from the document in a predetermined reflection direction, and performing photoelectric conversion,
First and second light beams are applied to the original from a first irradiation direction in which the reflected light is mainly diffusely reflected light and a second irradiation direction in which the reflected light is mainly specularly reflected light. Two light sources,
Reflection-side light guide means for guiding the reflected light to the photoelectric conversion means;
For each of the corresponding positions based on a comparison of the data of the positions corresponding to each other in the two image data generated by inputting the reflected light with respect to the light of each of the first and second light sources to the photoelectric conversion means. Image data synthesizing means for synthesizing the image data of the original by selecting any one of the data;
An image reading apparatus comprising: Image reading apparatus according to claim 1 comprising comprises a radiation direction switching means for switching between the irradiating light to both take the document of the first and second light sources. The image reading apparatus according to claim 2 , wherein the irradiation direction switching unit switches the irradiation direction each time the first and second light sources are moved to scan the entire image reading range of the document. The irradiation direction switching means, the first and second images according to claim 2 the entire image reading range of the document by moving the light source for each predetermined read units during scanning is intended for switching an irradiating direction Reader. Wherein the intensity of the illumination light to the document in the second irradiation direction, according to any of claims 1 to 4 consisting configured weaker than the intensity of the illumination light to the document of the first irradiation direction Image reader. The image reading apparatus according to claim 5 , wherein an optical path length from the second light source to the original is longer than an optical path length from the first light source to the original. The image reading apparatus according to claim 5 , further comprising a second light amount adjusting unit capable of adjusting a light passing amount in an optical path on the second light source side. The image reading apparatus according to claim 7, further comprising a light amount automatic adjustment unit that adjusts a light passage amount of the second light amount adjustment unit based on the image data generated by the photoelectric conversion unit. The image reading apparatus according to claim 7 , further comprising a first light amount adjusting unit capable of adjusting a light passage amount in an optical path on the first light source side. 9. consisting comprises a light amount automatic adjusting means for adjusting the passage of light of the first light amount adjusting means and the second light-quantity adjusting hand stage on the basis of the image data generated by said photoelectric conversion means The image reading apparatus described in 1. The predetermined reflection direction, the image reading apparatus according to any one of claims 1 to 10 which is an oblique direction with respect to the document surface. 2. The reflection-side light guide means includes a magic mirror, and the second light source passes light through the magic mirror and irradiates the original with light from the second irradiation direction. The image reading apparatus according to any one of 11 .   The image reading apparatus according to claim 1, wherein each of the first and second light sources has the same wavelength. In an image reading method for irradiating a document with light and photoelectrically converting reflected light reflected from the document in a predetermined reflection direction by a photoelectric conversion means to obtain image data of the document,
Each of the light from the first and second light sources is in each of a first irradiation direction in which the reflected light is mainly diffusely reflected light and a second irradiation direction in which the reflected light is mainly specularly reflected light. The reflected light of the irradiation light in each direction is photoelectrically converted by the photoelectric conversion means to obtain two image data, and the two image data are mutually corresponded by a predetermined image data synthesis means An image reading method for synthesizing image data of the original by selecting one of the data for each corresponding position based on the comparison of the data of the positions to be processed.

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