JP2018147382A - Optically-readable medium, correction method of optically-readable image, apparatus, and program - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an optically-readable medium formed by printing in a rewritable manner optically-readable information, such as an information code, on a medium having a reversible recording unit, which can solve the above problem.SOLUTION: An optically-readable medium has optically-readable information (150) printed on a medium. The optically-readable information includes a non-rewritable first printed part (110) and a rewritable second printed part (120).SELECTED DRAWING: Figure 1

Description

  The present invention relates to an optical reading medium, and an optically read image correction method, apparatus, and program.

  As means for recording information on a medium such as paper or plastic, an information code such as a one-dimensional code or a two-dimensional code is used. In particular, a two-dimensional code can have a lot of information in a small area compared to a one-dimensional code, so it is widely used for various purposes such as article management and web guidance using a mobile phone. .

  Such an information code is not only printed on a medium with a normal printing ink, but also printed on a medium having a reversible recording unit using a thermal head or the like (Patent Document 1). And 2).

  In this regard, Patent Document 2 prints an information code together with character information on a point card having a reversible recording unit using a thermal head, so that the user can confirm the point without requiring a complicated operation. It is proposed to provide a point card that can record digital information.

JP 2009-226679 A JP2015-055985A

  As described above, the information code is not only printed on a medium with a normal printing ink but also used for rewriting on a medium having a reversible recording unit using a thermal head or the like.

  In this regard, the inventors of the present invention, in the information code printed in such a rewritable manner, as the number of rewriting increases, the rewritable print remains unerased and lacks in color, thereby causing the information code to be read. I found it sometimes difficult.

  Therefore, the present invention provides an optical reading medium in which optical reading information such as an information code is rewritably printed on a medium having a reversible recording unit, and the above optical reading medium can be suppressed. The present invention also provides an optically read image correction method, apparatus, and program for suppressing errors in the analysis of such an optical read medium.

<1> An optical reading medium having optical reading information printed on the medium,
The optical read information has a first portion printed non-rewritable and a second portion printed rewritable;
Optical reading medium.
<2> The medium according to <1>, wherein the optical reading information is an information code, letters, numbers, marks, symbols, pictures, figures, photographs, or a combination thereof.
<3> The medium according to <2>, wherein the optical reading information is an information code.
<4> The medium according to <3>, wherein the information code is a one-dimensional code or a two-dimensional code.
<5> The first portion includes a functional pattern, and the second portion includes a data pattern.
The medium according to <3> or <4>.
<6> The information code is a one-dimensional code, and the functional pattern is selected from the group consisting of a start pattern, an end pattern, and a combination thereof.
The medium according to <5> above.
<7> The information code is a two-dimensional code, and the functional pattern is selected from the group consisting of a position detection pattern, a timing pattern, an alignment pattern, and combinations thereof.
The medium according to <5> above.
<8> Optical read image correction method including the following:
An image of the optical reading information of the optical reading medium according to any one of <1> to <7> is optically acquired, and at least one of the following steps (a) to (c): Correcting the above image by:
(A) In the image, the first and / or second portion is binarized based on color shading to correct the image,
(B) In the image, the color density of the first and / or second portion of the image is adjusted so that the difference in color density between the first and second portions is within a predetermined range. Correcting the image, and (c) in the image, the first and / or second of the image so that the positional relationship between the first and second portions is a predetermined positional relationship. Adjust the position of the part 2 to correct the image.
<9> The method according to <8>, wherein the image is corrected at least by the step (c).
<10> A method for reading optical read information, comprising analyzing the optical read information based on the image corrected by the method according to <8> or <9>.
<11> An optically read image correcting apparatus having the following:
An image acquisition unit that optically acquires an image of the optical reading information of the optical reading medium according to any one of <1> to <7>, and the following steps (a) to (c): An image processing unit that corrects the image by at least one of:
(A) In the image, the first and / or second portion is binarized based on color shading to correct the image,
(B) In the image, the color density of the first and / or second portion of the image is adjusted so that the difference in color density between the first and second portions is within a predetermined range. Correcting the image, and (c) in the image, the first and / or second of the image so that the positional relationship between the first and second portions is a predetermined positional relationship. Adjust the position of the part 2 to correct the image.
<12> Optical reading information reading device having the following:
The optical read image correcting device according to <11>, and an optical read information analyzing unit that analyzes the optical read information based on the corrected image.
<13> Optical read image correction program causing the processor to perform the following steps:
The image acquisition unit optically acquires the image of the optical reading information of the optical reading medium according to any one of <1> to <7>, and the following steps (a) to (c): ) To correct the image by at least one of:
(A) In the image, the first and / or second portion is binarized based on color shading to correct the image,
(B) In the image, the color density of the first and / or second portion of the image is adjusted so that the difference in color density between the first and second portions is within a predetermined range. Correcting the image, and (c) in the image, the first and / or second of the image so that the positional relationship between the first and second portions is a predetermined positional relationship. Adjust the position of the part 2 to correct the image.
<14> Optical reading information reading program causing the processor to perform the following steps:
Analyzing the optical read information based on the image corrected by the program according to the item <13>.

  In the optical reading medium of the present invention, it is possible to prevent the optical reading information from becoming difficult to read even when the number of rewrites is increased. In addition, according to the method, apparatus, and program of the present invention for correcting an optically read image, errors in analyzing the optical read medium of the present invention can be suppressed.

FIG. 1 is a diagram illustrating a card with a two-dimensional code as an example of the optical reading medium of the present invention. FIG. 2 is a diagram illustrating the layer structure of the optical reading medium of the present invention. FIG. 3 is a flowchart for explaining the process of binarizing the second portion based on the color density in the image of the optical reading information. FIG. 4 is a diagram for explaining the processing described in FIG. FIG. 5 adjusts the color density of the first and / or second portion so that the difference in color density between the first and second portions is within a predetermined range in the image of the optical reading information. It is a flowchart for demonstrating a process. FIG. 6 is a diagram for explaining the processing described in FIG. 7 adjusts the positions of the first and / or second portions so that the positional relationship between the positions of the first and second portions becomes a predetermined positional relationship in the image of the optical reading information. It is a flowchart for demonstrating a process. FIG. 8 is a diagram for explaining the processing described in FIG. FIG. 9 shows a two-dimensionally coded medium as an example of the optical reading medium of the present invention, in which a position detection pattern is printed in a non-rewritable manner using ordinary ink, and the data pattern is reversible by heat. It is a figure which shows the (a) visible image and (b) infrared image at the time of printing on the thermal recording layer so that rewriting is possible. FIG. 10 is a schematic diagram of the apparatus of the present invention for correcting and reading optically read images.

<Optical reading medium>
An optical reading medium of the present invention has optical reading information printed on a medium, and the optical reading information includes a first portion printed in a non-rewritable manner and a second portion printed in a rewritable manner. Have.

  In the use of the optical reading medium of the present invention, the images of the first and second parts of the optical reading information are acquired as a unit by an image acquisition device such as a camera, and the obtained image is processed by an image processor such as a processor. And processing by the optical reading information analysis unit. In other words, the first and second portions of the optical reading medium of the present invention integrally form optical reading information.

  According to such an optical reading medium of the present invention, even when the number of rewrites is increased and the second portion printed so as to be rewritable becomes unclear, the first non-rewritable printed first It is possible to suppress the reading of the entire optical reading information by virtue of the clear portion.

  The optical reading information may be an information code, letters, numbers, marks, symbols, pictures, figures, photographs, or combinations thereof. Therefore, even if the first and second parts of the optical reading information are integrated to form an information code, letters, numbers, marks, symbols, pictures, figures, photographs, or combinations thereof, the optical reading Each of the first and second portions of information may constitute one of an information code, letters, numbers, marks, symbols, pictures, photographs, figures, combinations thereof, or the like.

  For example, if the first part printed in a non-rewritable form is a graphic and the second part printed in a rewritable form is a photograph, this combination may be a student ID card or employee ID card. A combination of a frame for specifying the position of the face photo of the identification card and the face photo is mentioned. In this case, when the face photograph is optically read and recognized, the frame line can be used to specify the position of the face photograph.

  Also, for example, the first portion printed in a non-rewritable manner is a mark, a symbol, and / or a graphic, and the second portion printed in a rewritable manner is an information code, a character, and / or a number. In some cases, as this combination, for example, marks, symbols, and / or figures for specifying the position of rewritable information such as the number of points on the point card and rewritable information such as the number of points are printed. A combination with an information code, a character, and / or a number as information is mentioned. In this case, when optically reading and recognizing information such as an information code, characters, and / or numbers, marks, symbols, and / or figures can be used to specify this position.

  Examples of the information code as the optical reading information include a one-dimensional code and a one-dimensional code. Further, examples of the one-dimensional code include barcodes such as CODE39 (trademark), CODE128 (trademark), JAN (trademark), and ITF (trademark). Examples of the two-dimensional code include QR code (trademark) and PDF417 ( Trademark), data matrix (trademark), CP code (trademark), MaxiCode (trademark), and the like.

  When the optical reading information is an information code, each of the first and second parts may be a part of one information code.

  Thus, for example, when the optical reading information is an information code, the first and second portions may be the upper half and the lower half of one information code, respectively.

  For example, when the optical reading information is an information code, the first portion may be a function pattern, that is, a pattern for assisting in decoding data represented by a data pattern. Specifically, when the information code is a one-dimensional code, this function pattern may be a pattern selected from the group consisting of a start pattern, an end pattern, and a combination thereof, and the information code is two-dimensional. If it is a code, it may be a pattern selected from the group consisting of a position detection pattern, a timing pattern, an alignment pattern, and combinations thereof.

  Each of the start pattern and the end pattern means a pattern for representing both ends of the code in the one-dimensional code. In the two-dimensional code, the position detection pattern means a pattern for determining a data detection range, the timing pattern means a pattern for determining the coordinates of the data pattern, and the alignment pattern. Means a pattern for detecting distortion of a two-dimensional code.

  In this case, the second portion may be a pattern other than a data pattern, that is, a pattern other than a function pattern and having information to be recorded.

  As described above, when the optical reading medium according to the present invention is an information code-added medium, the number of rewrites increases, so that even when the second portion printed so as to be rewritable becomes unclear, the rewrite is impossible. Since at least the first printed portion can be read, it is possible to prevent the entire information code from being read.

  In particular, the first part printed non-rewritable includes a functional pattern, and the second part printed rewritable includes a data pattern, whereby at least the functional pattern is printed clearly. In some cases, the position where the data pattern should be located is specified by the function pattern, so that the entire two-dimensional code cannot be read even if the second portion printed rewritable becomes unclear. Can be suppressed.

  In the optical reading medium of the present invention, the non-rewritable printing may be any printing that cannot be rewritten in the mode of use of the optical reading medium, such as letterpress printing, gravure printing, offset printing, screen printing, electrostatic printing, It is selected from the group consisting of inkjet printing and laser printing.

  In addition, the rewritable printing may be any printing that can be rewritten in the mode of use of the optical reading medium, and in particular, may be rewritable printing printed on the reversible thermosensitive recording layer by heat. This reversible thermosensitive recording layer is, for example, a cloudy type reversible thermosensitive recording layer in which organic low molecules are dispersed in a resin base material, or a leuco type reversible sensitivity containing a leuco dye, a reversible developer and a resin. It may be a thermal recording layer.

  The medium on which the optical reading information is printed may be a tag, a card, particularly a paper or plastic card. Such a card may be, for example, as shown in FIG. 1. In this card (100), the information code (150) as optically read information printed on the medium cannot be rewritten. A position detection pattern (110) as a first portion printed on the printer and a data pattern (120) as a second portion printed rewritably.

  This card may be a point card, a membership card, a hospital examination ticket, or the like.

  The layer structure of the optical reading medium of the present invention may be, for example, as shown in FIG.

  That is, for example, as shown in FIG. 2 (a), the optical reading medium (210) of the present invention has a laser coloring substrate (214), a transparent substrate (216), and a rewrite on a core substrate (212). It can have a possible layer (218).

  When the optical reading medium of the present invention is a card, paper, PETG, PC, PVC (polyvinyl chloride) film or sheet can be used as the core substrate, and PETG (glycol-modified polyethylene) as the laser coloring substrate. Terephthalate), PC (polycarbonate) film can be used, PET (polyethylene terephthalate) film can be used as the transparent substrate, and a rewritable layer having a leuco dye can be used as the rewritable layer.

  In the embodiment shown in FIG. 2 (a), a laser-colorable substrate (214) is provided with a laser non-rewritable print (210a) during card manufacture, and at any subsequent time a thermal printer is applied to the rewritable layer. Can provide rewritable printing (210b).

  Therefore, when the optical reading medium of the present invention is a card, the card manufacturer at the time of manufacturing the card or the service provider who issues the card at the time of temporary issuing of the card performs non-rewritable printing on the laser coloring substrate by laser. A service provider that provides and then issues the card upon official card issue can provide rewritable printing on the reversible recording layer with a thermal printer.

  Further, for example, as shown in FIG. 2B, the optical reading medium (220) of the present invention has a rewritable layer (228) on the core substrate (222), and further has a non-rewritable layer thereon. Can have possible printing (220a).

  When the optical reading medium of the present invention is a card, paper, PETG, PC, PVC (polyvinyl chloride) film or sheet can be used as a core base material, and rewritable dye having a leuco dye as a rewritable layer Layers can be used. As the non-rewritable printing, as described above, any printing that cannot be rewritten in the mode of use of the optical reading medium, for example, offset printing, inkjet printing, and laser printing can be used.

  In the embodiment shown in FIG. 2 (b), a non-rewritable print (220a) is provided at the time of card manufacture, and a rewritable print (220b) is provided to the rewritable layer by a thermal printer at any subsequent time. be able to.

  Therefore, when the optical reading medium of the present invention is a card, the card manufacturer at the time of manufacturing the card or the service provider who issues the card at the time of temporary issuing of the card provides non-rewritable printing, and then the card A service provider that issues a card when the card is officially issued can provide rewritable printing by means of a thermal printer on the rewritable layer.

<Optical read image correction method>
The method of the present invention for correcting an optically read image includes:
Optically acquiring an image of the optical reading information of the optical reading medium of the present invention and correcting the image by at least one of the following steps (a) to (c):
(A) correcting the image by binarizing the first and / or second portion based on the color density in the image of the optical reading information;
(B) In the image of the optical reading information, the color density of the first and / or second portion of the image is adjusted so that the difference in color density between the first and second portions is within a predetermined range. (C) correcting the image, and (c) in the image of the optical reading information, the first and / or the first image and / or the second image of the first and / or second portion of the image so as to have a predetermined positional relationship. Adjust the position of the second part to correct the image.

  According to the method of the present invention, a problem that may occur with the optical reading medium of the present invention, that is, the first part of the optical reading information is printed in a non-rewritable manner, and the second part of the optical reading information is , Problems that may occur due to rewritable printing can be suppressed. Below, each of process (a)-(c) is demonstrated.

<Process (a) (binarization process)>
In the step (a), the image of the optical reading information is corrected by binarizing the first and / or second portion based on the color density in the optical reading information image.

  Specifically, as shown in FIG. 3, the process starts (310), obtains an image of optical read information (320), and the first and / or second portion of the image is transformed into a color. Binarization processing based on the shading (330) and termination of the processing (380). Here, the binarization processing converts the image into two gradations of white and black by converting to white if the pixel value is large and to black if the pixel value is small as compared with a predetermined threshold value. It may be a process.

  Such binarization processing is preferably performed for the second portion that is printed so as to be rewritable, particularly for the second portion that is repeatedly subjected to rewritable printing and erasure. The rewritable portion of the print may be left unprinted and insufficiently colored due to repeated printing and erasing. In such a case, the second portion of the image of the optically read information is changed to a shade of color. If binarization processing is performed based on this, errors in the analysis of the optical reading information can be suppressed.

  Specifically, in the case of such binarization, when the optical reading information is a two-dimensional code, as shown in FIG. 4A, the first portion (410) and the second portion (420) are divided. An image (400) of a two-dimensional code is obtained and, as shown in FIGS. 4 (b) and (c), a predetermined threshold value is used for the rewritable second portion (420). Thus, binarization is performed based on the color density, and a corrected image (450) as shown in FIG. 4D can be obtained. Specifically, this threshold value is converted to black at the place where the printing color is light and the printing color is light although it should be black (420a), and printing is originally present. It is preferable to select the portion (420b) that is colored by dirt or the like even though it should be white without being converted to white.

<Process (b) (Adjustment of color density)>
In step (b), the color of the first and / or second portion of the image is set so that the difference in color density between the first and second portions is within a predetermined range in the image of the optical reading information. Adjust the density to correct the image.

  Specifically, as shown in FIG. 5, this process starts (510), an image of optical read information is obtained (520), and the difference in color density between the first and second portions of the image is determined in advance. Adjusting the color density of the first and / or second portion of the image to be within the defined range (530) and terminating the process (580).

  The optical reading medium of the present invention has a first portion printed in a non-rewritable manner and a second portion printed in a rewritable manner. That is, the optical reading medium of the present invention has different types of printing in the first and second portions.

  In this case, the color density of the first and second portions of the image of the optical reading information may be different from each other. In such a case, the difference in color density between the first and second portions of the image is determined in advance. By adjusting the color density of the first and / or second portion of the image so that it falls within the specified range, errors in the analysis of the optical reading information can be suppressed.

  Specifically, when the optical reading information is a two-dimensional code, as shown in FIG. 6A, the adjustment of the color density is performed by the first part (610) and the second part (620). As shown in FIG. 6B, the color density of the first and second parts is compared, and the difference in color density between the first and second parts is obtained. A corrected image (650) as shown in FIG. 6C can be obtained by adjusting the color density of the first and / or second portion of the image so as to be within a predetermined range.

<Process (c) (Position adjustment)>
In the step (c), in the image of the optical reading information, the position of the first and / or second portion of the image is set so that the positional relationship between the first and second portions is a predetermined positional relationship. Adjust to correct the image.

  Specifically, as shown in FIG. 7, this process starts (710), obtains an image of optical reading information (720), and the positional relationship between the first and second portions of the image is determined in advance. Adjusting (730) the position of the first and / or second portion of the image to achieve the determined positional relationship and terminating (780) the process.

  The optical reading medium of the present invention has a first portion printed in a non-rewritable manner and a second portion printed in a rewritable manner. That is, in the optical reading medium of the present invention, the first and second portions are printed at different timings.

  In this case, the relative positions of the first and second portions of the image of the optical reading information may be shifted. In such a case, the positional relationship between the first and second portions of the image is If the positions of the first and / or second portions of the image are adjusted so as to have a predetermined positional relationship, errors in the analysis of the optical reading information can be suppressed.

  Specifically, when the optical reading information is a two-dimensional code, as shown in FIG. 8A, the relative position adjustment is performed by using the first portion (810) and the second portion ( 820), the two-dimensional code image (800) is obtained, and the first portion (810) and the second portion (820) are separately recognized as shown in FIG. Then, the position of the first and / or second portion of the image is adjusted so that their relative positions are in a predetermined positional relationship, and a corrected image (850) as shown in FIG. ) Can be obtained.

<Distinction between first part and second part>
If the first non-rewritable part is a part printed with normal ink, in particular a part printed with carbon-containing ink, the first part is visible and infrared To absorb both. On the other hand, when the second portion printed rewritable is rewritable printing printed on the reversible thermosensitive recording layer by heat, the second portion absorbs visible light but does not emit infrared light. Does not absorb. Therefore, by utilizing this fact, it is possible to distinguish between the first portion and the second portion, and to correct the image of the optical reading information based on the first portion and the second portion.

  Specifically, in this case, as shown in FIG. 9A, in the visible image (900) of the two-dimensional code, the first portion (900a) printed in a non-rewritable manner and the rewritable print are printed. Both prints of the second part (900b) are displayed. On the other hand, as shown in FIG. 9B, in the infrared image (950) of the two-dimensional code, the print of the first portion (950a) printed in a non-rewritable manner is displayed. On the other hand, the printing of the second portion (950b) printed so as to be rewritable is not displayed.

  Therefore, an image of the first portion (950a) printed in a non-rewritable manner can be obtained from the infrared image of the two-dimensional code shown in FIG. 9B. Further, a second rewritable printed image is obtained from the difference between the visible image (900) of the two-dimensional code shown in FIG. 9 (a) and the infrared image (950) of the two-dimensional code shown in FIG. 9 (b). An image of the portion (900b) can be obtained.

<Reading method of optical reading information>
The method of the present invention for reading optical read information includes analyzing the optical read information based on the image corrected by the method of the present invention.

  In this method, a generally known method can be used for analyzing the optical read information.

<< Optical Reading Image Correction Device and Optical Reading Information Reading Device >>
The apparatus of the present invention for correcting an optically read image has the following:
An image acquisition unit that optically acquires an image of optical reading information of the optical reading medium of the present invention, and an image processing unit that corrects an image by at least one of the following steps (a) to (c):
(A) correcting the image by binarizing the first and / or second portion based on the color density in the image;
(B) In the image, the color density of the first and / or second portion of the image is adjusted so that the difference in color density between the first and second portions is within a predetermined range, and the image And (c) adjusting the position of the first and / or second portion of the image so that the positional relationship between the first and second portions becomes a predetermined positional relationship in the image. And correct the image.

The apparatus of the present invention for reading optical read information also has the following:
An optically read image analyzing apparatus according to the present invention, and an optically read information analyzing unit that analyzes optically read information based on the corrected image.

  As shown in FIG. 10, in the apparatus (1000) of the present invention, the image acquisition unit (1020) may be a camera, and the image processing unit and the optical reading information analysis unit are a processing unit (1010) such as a processor. It may be. As shown in FIG. 10, the apparatus (1000) of the present invention includes a storage unit (1030) such as a memory, a display unit (1040) such as a display, and an operation unit (1050) such as a touch panel. be able to. Therefore, in the apparatus of the present invention, the operation unit is used for selecting an image to be acquired, the analysis result of the optical reading information is displayed on the display unit, and the analysis result of the optical reading information is stored in the storage unit. Can do. For details of the apparatus of the present invention, the description relating to the method of the present invention can be referred to.

<< Optical Reading Image Correction Program and Optical Reading Information Reading Program >>
The program of the present invention for correcting an image of optical read information causes a processor to perform the following steps:
An image of the optical reading information of the optical reading medium of the present invention is optically acquired by the image acquisition unit, and the image is corrected by at least one of the following steps (a) to (c):
(A) correcting the image by binarizing the first and / or second portion based on the color density in the image;
(B) In the image, the color density of the first and / or second portion of the image is adjusted so that the difference in color density between the first and second portions is within a predetermined range, and the image And (c) adjusting the position of the first and / or second portion of the image so that the positional relationship between the first and second portions becomes a predetermined positional relationship in the image. And correct the image.

Also, the program of the present invention for reading optical read information causes a processor to perform the following steps:
Analyzing optical read information based on an image corrected by the program of the present invention.

  For details of the program of the present invention, the description relating to the method and apparatus of the present invention can be referred to.

100 cards (optical reading media)
110 Position detection pattern 120 Data pattern 150 Optical reading information 210, 220 Optical reading medium 210a, 220a Non-rewritable printing 210b, 220b Rewritable printing 400, 600, 800 Two-dimensional code image 410, 610, 810 First part 420 , 620, 820 Second part 450, 650, 850 Corrected image 900 Two-dimensional code visible image 900a Non-rewritable first part in visible image 900b Second rewritable printed in visible image Part 950 Infrared image of two-dimensional code 950a First non-rewritable part in infrared image 950b Second part rewritably printed in infrared image

Claims (14)

An optical reading medium having optical reading information printed on the medium,
The optically read information has a first portion printed in a non-rewritable manner and a second portion printed in a rewritable manner;
Optical reading medium.   The medium according to claim 1, wherein the optical reading information is an information code, letters, numbers, marks, symbols, pictures, figures, photographs, or a combination thereof.   The medium according to claim 2, wherein the optical reading information is an information code.   The medium according to claim 3, wherein the information code is a one-dimensional code or a two-dimensional code. The first portion includes a functional pattern, and the second portion includes a data pattern;
The medium according to claim 3 or 4. The information code is a one-dimensional code, and the functional pattern is selected from the group consisting of a start pattern, an end pattern, and a combination thereof.
The medium according to claim 5. The information code is a two-dimensional code, and the functional pattern is selected from the group consisting of a position detection pattern, a timing pattern, an alignment pattern, and a combination thereof.
The medium according to claim 5. Optical reading image correction methods, including:
An image of the optical reading information of the optical reading medium according to any one of claims 1 to 7 is optically acquired, and the image is obtained by at least one of the following steps (a) to (c): To correct:
(A) correcting the image by binarizing the first and / or second portion based on color shading in the image;
(B) In the image, the color density of the first and / or second portion of the image is adjusted so that the difference in color density between the first and second portions is within a predetermined range. Correcting the image; and (c) in the image, the first and / or second of the image so that the positional relationship between the first and second portions is a predetermined positional relationship. Adjusting the position of the portion 2 to correct the image.   9. The method of claim 8, wherein the image is corrected at least by step (c).   A method for reading optical read information, comprising: analyzing the optical read information based on the image corrected by the method according to claim 8. An optically read image correction device having:
An image acquisition unit that optically acquires an image of the optical reading information of the optical reading medium according to any one of claims 1 to 7, and at least one of the following steps (a) to (c): An image processing unit for correcting the image by:
(A) correcting the image by binarizing the first and / or second portion based on color shading in the image;
(B) In the image, the color density of the first and / or second portion of the image is adjusted so that the difference in color density between the first and second portions is within a predetermined range. Correcting the image; and (c) in the image, the first and / or second of the image so that the positional relationship between the first and second portions is a predetermined positional relationship. Adjusting the position of the portion 2 to correct the image. Optical reading information reader having:
An optical reading information analyzing unit according to claim 11, and an optical reading information analyzing unit that analyzes the optical reading information based on the correction image. Optical read image correction program that causes the processor to perform the following steps:
An image of the optical reading information of the optical reading medium according to any one of claims 1 to 7 is optically acquired by an image acquisition unit, and at least one of the following steps (a) to (c): Correcting the image by:
(A) correcting the image by binarizing the first and / or second portion based on color shading in the image;
(B) In the image, the color density of the first and / or second portion of the image is adjusted so that the difference in color density between the first and second portions is within a predetermined range. Correcting the image; and (c) in the image, the first and / or second of the image so that the positional relationship between the first and second portions is a predetermined positional relationship. Adjusting the position of the portion 2 to correct the image. Optical reading information reading program that causes the processor to perform the following steps:
The optical reading information is analyzed based on the image corrected by the program according to claim 13.