JP6003335B2 - Information recording medium reading method and information recording medium - Google Patents

Description

  The present invention relates to a method for reading an information recording medium using an infrared light emitting layer, and an information recording medium.

  In an information recording medium on which image information such as letters and bar codes is recorded, such as a lottery and a ticket, image information is generally formed so that anyone can see it. Therefore, there is a possibility of being counterfeited or tampered with by others. Therefore, a technique for preventing forgery and the like by making image information invisible and reading it with a predetermined reading device has been proposed.

  As an example of this, there are many methods in which image information that cannot be seen with the naked eye is formed using ink that emits visible light when excited with ultraviolet light, and is read with a visible light receiving sensor that is excited with ultraviolet light. However, since this method is widely recognized and it is easy to obtain ink materials, there is a problem that the effect of preventing counterfeiting is low.

  Therefore, a method has been proposed in which image information formed of a material that absorbs infrared light and an infrared light emitting layer that emits infrared light when excited by infrared light are stacked, and the image information is concealed and image information is read by an infrared reader.

For example, in Patent Document 1, an infrared light emitting layer is formed on a substrate, image information using an infrared absorbing material is formed thereon, and a concealing layer that absorbs part of visible light is formed thereon. For a medium, a method for reading image information by a reading device is described.
Patent Document 2 discloses a method of reading image information with a reading device on a medium in which image information is formed of an infrared absorbing material on a base material, an infrared light emitting layer is formed thereon, and the image information is thereby hidden. Is described.

Registered Utility Model No. 3013328 JP 2001-96889 A

  By using the above method, even when the image information is hidden so as not to be visible, it can be read by an infrared reader, and ink materials and the like are relatively difficult to obtain. However, even in such a case, the possibility that the information recording medium is counterfeited cannot be denied. In particular, it is necessary to increase the security of things that may have a high monetary value, such as lotteries.

  The present invention has been made in view of the above-described problems, and an object of the present invention is to provide a method for reading an information recording medium that can be read by infrared rays and can improve anti-counterfeiting.

  In the first invention for achieving the above-described object, an infrared light having a peak wavelength different from that of the excitation light is excited on or below the image information that absorbs the infrared light formed on the substrate by the excitation light by the infrared light. An irradiation step of irradiating an information recording medium having a light emitting infrared light emitting layer with excitation light, and receiving infrared light emitted from the infrared light emitting layer through a filter that cuts the peak wavelength of the excitation light. And determining whether the information recording medium is true or not by analyzing the infrared light received in the light receiving step, and determining whether the information recording medium is true in the authenticity determining step. And a reading step of reading the image information from the infrared light received in the light receiving step.

  When the information recording medium configured as described above is irradiated with infrared excitation light, the infrared light emitting layer is excited and emits infrared light having a peak wavelength different from that of the excitation light. In the reading method of the first invention, by analyzing the infrared ray, the authenticity of the information recording medium is determined depending on whether the infrared ray emitting layer uses a regular material, and then the infrared ray emitting layer emitting the infrared ray. Then, the image information can be read from the contrast of the image information that absorbs infrared rays. Thereby, the forged information recording medium can be invalidated. In addition, since only one type of infrared light is used for excitation, the reader can be configured with a simple configuration, and there is an advantage that reading can be easily performed by cutting the excitation light.

In the light receiving step, infrared light is received for each of the plurality of wavelength regions of the infrared light emitted by the infrared light emitting layer, and in the authenticity determination step, based on the amount of infrared light received in the plurality of wavelength regions, It is desirable to determine the authenticity of the information recording medium.
Thus, the difference between the infrared light emitting layer using a regular material and other infrared light emitting layers can be easily determined by using the amount of infrared light received for each wavelength region.

The infrared light emitted by the infrared light emitting layer is a peak of infrared light emitted by the infrared light emitting layer between the first wavelength region and the second wavelength region where the light emission intensity is a value equal to or greater than a predetermined light emission intensity threshold value. It is desirable to have a wavelength at which the emission intensity is at least 30% of the emission intensity of the wavelength and lower than the emission intensity threshold.
As described above, the infrared light emitted from the infrared light emitting layer has a characteristic distribution having a plurality of wavelength regions having a large light emission intensity and a large valley portion therebetween, thereby facilitating authenticity determination and the infrared light emitting layer. It is also difficult to forge.

In the authenticity determination step, at least an infrared light reception amount in the first wavelength range determined according to the emission intensity threshold is equal to or greater than a first predetermined value, the first wavelength range, and the light emission when the amount of light received by the infrared third wavelength region is between the second wavelength range determined according to the intensity threshold value is less than the second predetermined value, determines that the true the information recording medium be able to. At this time, it is preferable that the reading step reads the image information based on infrared rays in the second wavelength range.
Further, in the authenticity determination step, the amount of received infrared light in the first wavelength range determined according to the emission intensity threshold is equal to or more than a first predetermined value, the first wavelength range, and the light emission amount of received infrared third wavelength region is less than a second predetermined value which is between the second wavelength range that is determined in accordance with the intensity threshold, and the light receiving amount of the infrared of the second wavelength region May be determined to be true when is equal to or greater than a third predetermined value.

  In this way, by performing authenticity determination and image reading using received light amounts in a plurality of types of wavelength regions, the authenticity determination and image reading mechanisms can be complicated, and it is difficult to create counterfeit products and the like.

  In the second invention, an infrared light emitting layer that emits infrared light having a peak wavelength different from that of excitation light that is excited by infrared excitation light is formed on or under image information that absorbs infrared light formed on a substrate. The infrared light emitted from the infrared light emitting layer is an infrared light emitted from the infrared light emitting layer between the first wavelength region and the second wavelength region where the light emission intensity is equal to or greater than a predetermined light emission intensity threshold value. An information recording medium having a wavelength at which the emission intensity is at least 30% of the emission intensity at the peak wavelength and lower than the emission intensity threshold value.

  In the information recording medium of the second invention, the infrared light emitted from the excited infrared light emitting layer has a characteristic spectral distribution having a plurality of wavelength regions having a large light emission intensity and a large valley portion therebetween. Therefore, the authenticity of the information recording medium can be easily determined. Therefore, the information recording medium is particularly suitable for the reading method of the first invention, and it is difficult to forge the infrared light emitting layer. On the other hand, it is also possible to read image information by infrared rays from the contrast of the infrared light emitting layer that emits infrared rays and the image information that absorbs infrared rays. In addition, since only one type of infrared ray is used for excitation, the reader can be configured with a simple configuration, and there is an advantage that authenticity determination and reading can be easily performed by cutting the excitation light.

The infrared light emitting layer preferably includes a plurality of types of phosphors that emit infrared rays having different peak wavelengths when excited with the same excitation light.
As a result, the information recording medium of the second invention can be easily prepared, and forgery is further difficult because a plurality of types of phosphors are used.

The infrared light emitting layer may be formed on the image information, or the image information may be formed on the infrared light emitting layer.
In the former case, it is easy to form an infrared light emitting layer so as to cover only preprinted image information, and there is an advantage that the amount of material consumption can be easily suppressed. Further, there is an advantage that an infrared light emitting layer can be provided later only on a necessary portion on the medium after the printing of the image information is completed.
On the other hand, in the latter case, there is an advantage that higher contrast can be obtained at the edge portion of the image information on the data obtained by reading the image information.

The image information is preferably covered with a material that transmits infrared light and reflects or absorbs visible light.
In this case, since the image information becomes invisible to the naked eye, the forgery prevention property can be further improved.

  According to the present invention, it is possible to provide a method of reading an information recording medium that can be read by infrared rays and can improve anti-counterfeiting.

The figure shown about the information recording medium 1 The figure explaining the infrared rays light emitting layer 15 The figure explaining the reader 50 The figure which shows the hardware constitutions of the information processing apparatus 55 A flowchart showing the flow of authenticity determination of the information recording medium 1 and reading of the image information 13 The figure shown about the authenticity determination logic of the information recording medium 1 The figure shown about the reading result of the image information 13 The figure shown about information recording media 1a and 1b Figure showing lottery 1c The figure shown about the sealing material 80 and the inspection medium 1d The figure which shows the spectrum of the infrared rays which the infrared rays light emitting layer 15 light-emits

  Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.

[First Embodiment]
(Configuration of information recording medium 1)
FIG. 1 is a diagram showing an information recording medium 1 according to the first embodiment of the present invention.

  As shown in FIG. 1, in the information recording medium 1, image information 13 is formed on a base material 11, and an infrared light emitting layer 15 is provided on the image information 13 and the base material 11. Further, an infrared transmission / visible light reflection / absorption layer 17 is provided on the infrared light emitting layer 15 so as to overlap therewith. In the term of infrared transmission / visible light reflection / absorption layer 17, “·” means “and”, and “/” means “or”. That is, the infrared transmission / visible light reflection / absorption layer 17 is a “layer that transmits infrared light and reflects or absorbs visible light”.

  The base material 11 is, for example, various types of paper for printing, but other materials such as plastic are not particularly limited.

The image information 13 is formed by printing with ink containing a material that absorbs infrared rays such as carbon black. For example, printing with black ink containing carbon that is generally used may be performed. In addition, if the material contains carbon or the like and absorbs infrared rays, the image information 13 can be formed using the material. Alternatively, it is also possible to form a pattern that absorbs infrared rays as the image information 13 by irradiating the substrate 11 such as a resin with a laser.
The image information 13 is, for example, barcode information, two-dimensional code, OCR numbers, numbers, characters, designs, symbols, etc., but is not limited thereto.

The infrared light emitting layer 15 is formed by solid printing a fluorescent material including a phosphor that is excited by irradiating infrared light as excitation light and emits infrared light having a peak wavelength different from that of the excitation light.
In the present embodiment, two types of phosphors that emit infrared light having different peak wavelengths when the same excitation light is irradiated are used as the phosphors. As a result, the infrared light emitted from the infrared light emitting layer 15 has two wavelength regions with high emission intensity. This will be described later. The light emission intensity indicates the amount of light and corresponds to a general light measurement amount such as luminous intensity. In addition, the peak wavelength indicates a wavelength with the highest emission intensity.

  Further, the solid printing of the infrared light emitting layer 15 may be performed by offset printing, gravure printing, flexographic printing, screen printing, pad printing, or the like, or the infrared light emitting layer 15 is formed on the substrate 11 using a transfer sheet, a label, or the like. You may make it form in. The infrared light emitting layer 15 may be formed by applying the fluorescent material by spraying.

The infrared transmission / visible light reflection / absorption layer 17 transmits the infrared rays and reflects or absorbs the visible light, thereby making the image information 13 invisible to the naked eye.
The infrared transmissive / visible light reflecting / absorbing layer 17 only needs to contain a material that transmits infrared light and reflects or absorbs visible light, and various materials can be used. For example, a black layer in which cyan, magenta, and yellow pigments are dispersed, an orange layer in which magenta and yellow pigments are dispersed, and a green layer in which cyan and yellow pigments are dispersed can be used. The infrared transmission / visible light reflection / absorption layer 17 can be formed by printing.

(Infrared light emitting layer 15)
FIG. 2A schematically shows the spectral distribution of infrared light emitted during excitation for each of the two types of phosphors A and B included in the infrared light emitting layer 15. The vertical axis represents the ratio (%) of the emission intensity at each wavelength to the emission intensity at the peak wavelength. The excitation light having a peak wavelength of about 810 nm is used.

  As shown in the figure, the phosphor of the infrared light emitting layer 15 includes, for example, a phosphor A that emits infrared light having a peak wavelength 21 of about 900 nm when irradiated with excitation light having a peak wavelength of about 810 nm. A phosphor B that emits infrared rays having a wavelength 23 of about 1000 nm is included.

FIG. 2B schematically shows the state of infrared light emission of the infrared light emitting layer 15.
For example, when the information recording medium 1 is irradiated with excitation light 41 having a peak wavelength of about 810 nm, the excitation light 41 passes through the infrared transmission / visible light reflection / absorption layer 17 and reaches the infrared light emitting layer 15. To do.

  The excitation light 41 that has reached the infrared light emitting layer 15 excites the phosphors A and B contained in the infrared light emitting layer 15. Thereby, the infrared light emitting layer 15 emits an infrared ray 43 having a peak wavelength 21 of about 900 nm and an infrared ray 44 having a peak wavelength 23 of about 1000 nm. The emitted infrared rays 43 and 44 pass through the infrared transmission / visible light reflection / absorption layer 17 and can be received from the outside.

  FIG. 2C is a diagram schematically showing the spectrum distribution of the infrared light emitted from the infrared light emitting layer 15. This spectral distribution is a combination of the spectral distributions of infrared rays emitted from the phosphors A and B.

  In this spectrum distribution, the wavelength regions having an emission intensity equal to or greater than the emission intensity threshold value 25 are defined as wavelength regions 31 and 35. One of these wavelength ranges 31 and 35 corresponds to the first wavelength range in the present invention, and the other corresponds to the second wavelength range. In the present embodiment, the light emission intensity threshold 25 is set to a value of about 50% of the light emission intensity at the peak wavelength 20, and the wavelength regions 31 and 35 are ranges centered at wavelengths of about 900 nm and about 1000 nm, respectively. ing. However, the emission intensity threshold 25 can be determined as appropriate.

  In this spectral distribution, a wavelength portion 27 lower than the emission intensity threshold 25 by a width 26 corresponding to at least 30% of the emission intensity at the peak wavelength 20 is generated between the wavelength ranges 31 and 35. .

  That is, when the emission intensity threshold 25 is set to a predetermined value, this spectral distribution is a value of 30% of the emission intensity at the peak wavelength 20 between the wavelength regions 31 and 35 having emission intensity equal to or higher than that value. As described above, the light emission has a wavelength lower than the light emission intensity threshold 25, and has a characteristic distribution having a plurality of wavelength regions having high light emission intensity and a large valley portion therebetween. This facilitates authenticity determination of the information recording medium 1 described later, and makes it difficult to forge the infrared light emitting layer 15.

  Here, a predetermined wavelength region centered at a wavelength of about 925 nm between the wavelength regions 31 and 35 is defined as a wavelength region 33. This wavelength region 33 corresponds to the third wavelength region in the present invention. The amount of infrared light received in each wavelength band 31, 33, 35 is used for authenticity determination and reading of the information recording medium 1 described later. The amount of received light refers to the amount of light received.

(Reading method of information recording medium 1)
Next, a method for reading the information recording medium 1 will be described with reference to FIGS.

  As shown in FIG. 3A, reading of the information recording medium 1 is performed using a reading device 50 and an information processing device 55 connected thereto.

The reading device 50 includes an infrared irradiation device 51, an infrared light receiving device 53, and the like.
The infrared irradiation device 51 is, for example, a light emitting diode or the like, and irradiates the information recording medium 1 with infrared rays as excitation light. In this embodiment, the information recording medium 1 is irradiated with excitation light having a peak wavelength of about 810 nm by the infrared irradiation device 51. However, the infrared irradiation device 51 is not limited to this.

  The infrared light receiving device 53 receives infrared light emitted from the infrared light emitting layer 15 of the information recording medium 1. As shown in FIG. 3B, the infrared light receiving device 53 includes three infrared cameras 73, 75, and 77, and filters 63, 65, and 67 attached to the light receiving surfaces of the infrared cameras 73, 75, and 77, respectively. Consists of.

  The infrared cameras 73, 75, and 77 receive infrared light emitted from the infrared light emitting layer 15 by excitation by a plurality of light receiving elements, and convert the amount of light received by each light receiving element into a pixel value that is a luminance value on an image. An imaging device. The infrared cameras 73, 75, 77 are not particularly limited as long as they have sensitivity in the infrared region.

  The filter 63 attached to the infrared camera 73 transmits only infrared rays in the wavelength region 31 shown in FIG. On the other hand, the filter 65 attached to the infrared camera 75 transmits only infrared rays in the wavelength region 33 shown in FIG. Further, the filter 67 attached to the infrared camera 77 transmits only infrared rays in the wavelength region 35 shown in FIG. These filters also cut the peak wavelength of the excitation light.

  As described above, the infrared cameras 73, 75, and 77 receive the infrared rays in the wavelength regions 31, 33, and 35 by the light receiving element, and the received light amount data is sent to the information processing device 55. The infrared light emission intensity shown in FIG. 2 (c) indicates the amount of light at each wavelength of the infrared light as described above. Therefore, when infrared light having a large light emission intensity such as the wavelength bands 31 and 35 is received, The amount of light received increases. On the other hand, in the case of receiving infrared rays in a wavelength region where the emission intensity is small as in the wavelength region 33, the amount of received light is small. Based on the amount of light received in each wavelength region, authenticity determination of the information recording medium 1 and reading processing of the image information 13 described later are executed.

  The infrared cameras 73, 75, 77 and the infrared irradiation device 51 may be provided integrally. FIG. 3C shows an example, in which an infrared irradiation device 51 is arranged in a ring shape so as to surround the infrared cameras 73, 75, and 77 on which the filters 63, 65, and 67 are mounted.

  On the other hand, as shown in FIG. 4, the information processing apparatus 55 can be realized by a general-purpose computer or the like in which a control unit 101, a storage unit 102, an input unit 103, a display unit 104, a communication unit 105, and the like are connected by a bus 106. . The storage unit 102 stores a program for performing authenticity determination of the information recording medium 1 to be described later, reading of the image information 13, and the like. By executing the program, processing described later can be performed.

  FIG. 5 is a flowchart for explaining the procedure of authenticating the information recording medium 1 and reading the image information 13 by the information processing apparatus 55.

  As described above, in the reading device 50, the information recording medium 1 is irradiated with excitation light, and the infrared light emitted from the infrared light emitting layer 15 is received by the light receiving elements of the infrared cameras 73, 75, and 77. The control unit 101 of the information processing apparatus 55 receives the data of the received light amount of the infrared light in the wavelength regions 31, 33, and 35 received by the light receiving elements of the infrared cameras 73, 75, and 77 (step S1).

  Next, the control unit 101 of the information processing device 55 first determines the authenticity of the information recording medium 1 based on the received light amount data of the wavelength regions 31, 33, and 35 (step S2).

  Here, it is assumed that infrared rays are detected in each wavelength region when the amount of light received in each wavelength region 31, 33, 35 is equal to or greater than a predetermined value determined in accordance with each wavelength region 31, 33, 35. , 35 and when the infrared ray in the wavelength region 33 is not detected, the information recording medium 1 is set to be true. The value of the amount of light received in each wavelength region 31, 33, 35 is the amount of light received per infrared camera, for example, the sum of the amount of light received by each light receiving element of one infrared camera. However, the present invention is not limited to this. For example, one infrared camera may use one light receiving element having the largest amount of received light or the amount of received light received by a specific light receiving element.

  In the determination of S2, there are eight combinations of infrared detection / non-detection in each of the wavelength regions 31, 33, and 35 as shown in FIG. In the case 3 of FIG. 6 in which the infrared ray in the area 33 is not detected, it is determined that the information recording medium 1 is true. On the other hand, in other cases 1, 2, 4 to 8, since another phosphor is used for the infrared light emitting layer 15, it is determined that the information recording medium 1 is false.

  When it is determined that the information recording medium 1 is true (step S2; true), the control unit 101 of the information processing device 55 performs a reading process of the image information 13 and converts the image data of the image information 13 into the information processing device 55. The information is displayed on the display unit 104 (step S3).

In the present embodiment, image data obtained by converting the amount of light received by each infrared light receiving element in the wavelength region 35 into a pixel value is displayed. An example of this image data is shown in FIG.
As described above, the infrared light emitting layer 15 emits infrared light, and the image information 13 absorbs infrared light. Therefore, in the image data, the infrared light emitting layer 15 is a portion having a high luminance except for a portion where the image information 13 is formed below. Appears as On the other hand, the portion of the image information 13 appears as a portion having a lower luminance than the surrounding infrared light emitting layer 15. Therefore, the image information 13 can be read from this contrast.

  Although the infrared light emitting layer 15 is formed on the image information 13, the image information 13 appears as a low-brightness part on the image data because the amount of phosphor contained in the infrared light emitting layer 15 is dispersed. However, the image information 13 below is shown on the image in a portion other than the phosphor, and the infrared light emitted from the phosphor is reflected on the substrate 11 and enters the infrared camera 77. This is because the portion of the image information 13 that absorbs infrared rays has a lower brightness than the portion other than the image information 13 to be performed. Further, the film thickness of the infrared light emitting layer 15 on the image information 13 is thinner than other portions, which contributes to the appearance of the portion of the image information 13 as a low luminance portion.

  However, the reading of the image data is not limited to this, and the image information 13 may be read from infrared rays in the wavelength region 31, or a filter that transmits infrared rays in a wide wavelength region including the wavelength regions 31 and 35 may be used. An attached infrared camera may be provided separately so that the image information 13 may be read by receiving infrared rays in a wide wavelength range.

  On the other hand, when the information recording medium 1 is determined to be false in S2 (step S2; false), the processing of S3 is not performed and the information recording medium 1 is displayed as false on the display unit 104 of the information processing device 55. The process is terminated, for example, by displaying.

  In the authenticity determination process of S2, only one of the wavelength region 31 or the wavelength region 35 and the infrared ray of the wavelength region 33 are used for the determination, and in reading the image information 13 of S3, the other of the wavelength region 31 or the wavelength region 35 is used. Infrared rays may be used.

For example, when the infrared ray in the wavelength band 31 is detected in S2 and the infrared ray in the wavelength band 33 is not detected, the image information 13 may be read from the infrared ray in the wavelength band 35 in S3.
At this time, in S2, the determination result of the information recording medium 1 is true also in case 4 in addition to case 3 in FIG. 6, but in case 4, infrared light in the wavelength region 35 is not detected. The image information 13 cannot be read, and substantially the same effect as described above can be obtained.

  As described above, according to the present embodiment, when the information recording medium 1 is irradiated with infrared excitation light, the infrared light emitting layer 15 is excited and emits infrared light having a peak wavelength different from that of the excitation light. Then, by analyzing the amount of received light for each of the infrared wavelength regions 31, 33, 35 emitted by the infrared light emitting layer 15, it is easy to authenticate the information recording medium 1 depending on whether the infrared light emitting layer 15 uses a regular material. Can be determined. In addition, the image information 13 can be read from the contrast of the infrared light emitting layer 15 that emits infrared light and the image information 13 that absorbs infrared light. Thereby, the forged information recording medium 1 can be invalidated. In addition, since only one type of infrared ray is used for excitation, the reading device 50 can be configured with a simple configuration, and reading can be easily performed by cutting the excitation light.

  The infrared light emitting layer 15 of the information recording medium 1 includes a plurality of types of phosphors that emit infrared light having different peak wavelengths when excited with the same excitation light. As a result, the infrared light emitted from the infrared light emitting layer 15 has a characteristic distribution having a plurality of wavelength regions 31 and 35 having high light emission intensity and a large valley portion therebetween as described with reference to FIG. Therefore, the authenticity of the information recording medium 1 can be easily determined, and it is difficult to forge the infrared light emitting layer 15.

  In particular, in the present embodiment, as described with reference to FIG. 2C, the infrared light emitted from the infrared light emitting layer 15 of the information recording medium 1 is transmitted between the wavelength regions 31 and 35 where the light emission intensity threshold value is 25 or more. In addition, a wavelength portion 27 lower than the emission intensity threshold 25 by a width 26 corresponding to at least 30% of the emission intensity of the peak wavelength 20 is generated.

For example, several small peaks and valleys are observed even in the infrared spectral distribution emitted by one type of phosphor, such as the infrared spectral distribution emitted by phosphor A shown in FIG. This is because there is a case.
That is, when the width 26 is set to be less than 30% of the emission intensity at the peak wavelength 20, the information recording medium using one type of phosphor in the authenticity determination logic of this embodiment has a small spectral distribution. There is a risk that this may be true due to a valley or valley, but this is prevented by setting the width 26 to be at least 30% of the emission intensity of the peak wavelength 20, and information using two or more kinds of phosphors having different peak wavelengths is used. The recording medium can be identified as a true information recording medium that emits infrared light having a characteristic spectral distribution as described above.

  Note that a case where such a characteristic spectral distribution is realized by using one kind of phosphor is also conceivable. For example, the infrared light emitting layer 15 made of one kind of phosphor has a plurality of wavelength regions 31 and 35 having a large light emission intensity and a large valley portion between them as described with reference to FIG. In this case, infrared light having a typical spectral distribution is emitted. Even in such a case, in this embodiment, it is identified as a true information recording medium. This is because the phosphor itself is already characteristic.

Furthermore, in the information recording medium 1, since the infrared light emitting layer 15 is formed on the image information 13, it is easy to form the infrared light emitting layer 15 so as to cover only the preprinted image information 13, and the consumption of materials There is an advantage that the amount can be easily suppressed. Further, there is an advantage that the infrared light emitting layer 15 can be applied later only to a necessary part on the medium after the printing of the image information 13 is completed.
In addition, since the image information 13 is covered with the infrared transmission / visible light reflection / absorption layer 17, the image information 13 can be made invisible to the naked eye, and the anti-counterfeiting property can be further improved.

  In addition, by using the amount of received light in a plurality of types of wavelengths by the above-described logic, authenticity determination and image reading can be performed, so that the mechanism of authenticity determination and image reading can be complicated, and counterfeit products etc. It becomes difficult to create.

  However, the logic of true / false determination is not limited to the above, and any logic can be used as long as it can distinguish the spectral distribution of the normally formed infrared light emitting layer 15 from others. Accordingly, various cases can be considered for the spectral distribution of the infrared light emitting layer 15, and the infrared light emitting layer 15 is not limited to that described in this embodiment.

  Next, other examples of the present invention will be described as second to fifth embodiments. In addition, description of each embodiment is given about a different point from 1st Embodiment, and description is abbreviate | omitted about the same point.

[Second Embodiment]
FIG. 8A shows an information recording medium 1a according to the second embodiment of the present invention. As shown in the figure, this information recording medium 1a is different from the first embodiment in that the infrared transmission / visible light reflection / absorption layer 17 is omitted.

  Also in the second embodiment, the image information 13 can be read after the authenticity determination of the information recording medium 1a is performed in the same manner as in the first embodiment, which is the same as in the first embodiment. An effect is obtained. Thus, in some cases, the infrared transmission / visible light reflection / absorption layer 17 may not be provided.

[Third Embodiment]
FIG. 8B shows an information recording medium 1b according to the third embodiment of the present invention. This information recording medium 1b is different from the first embodiment in that the image information 13 is provided on the infrared light emitting layer 15 in an overlapping manner.

  Also in the third embodiment, the image information 13 can be read after the authenticity determination of the information recording medium 1b is performed in the same manner as in the first embodiment, which is the same as in the first embodiment. An effect is obtained. In the third embodiment, when the excitation light is irradiated, the image information 13 absorbs the excitation light, so that the underlying infrared light emitting layer 15 is difficult to be excited. There is an advantage that higher contrast can be obtained in a part.

[Fourth Embodiment]
Next, an example in which the information recording medium 1 of the first embodiment is used as a lottery 1c will be described as a fourth embodiment. FIG. 9A shows a cross-sectional configuration of the lottery 1c. FIG. 9B shows the top surface of the lottery 1c.

  The lottery 1c is formed by forming the image information 13 on the base material 11 and superposing the infrared light emitting layer 15 thereon, and further transmitting the infrared light and reflecting the visible light so as to cover the image information 13 and the infrared light emitting layer 15. / Absorptive layer 17 is formed. In the present embodiment, image information 45 that can be read under visible light is further formed in the infrared transmission / visible light reflection / absorption layer 17. Here, the image information 45 is an OCR number indicating a lottery number, and the image information 13 is a bar code indicating a corresponding number. However, each image information is not limited to this.

  Similarly to the first embodiment, the lottery 1c can also read the image information 13 after authenticity determination. In this embodiment, a reading device (not shown) for reading the image information 45 is connected to the information processing device 55, and the read image information 13 and the reading result of the image information 45 are collated. The authenticity of the lot 1c can be checked twice. The lottery 1c may have a high monetary value and is strongly required to be authentic. Therefore, it is particularly effective to improve security.

[Fifth Embodiment]
As the fifth embodiment, an example in which the information recording medium 1a of the second embodiment is used as an inspection medium 1d used for inspecting whether the inclusion 22 and its destination match in the sealed object 80. explain. FIG. 10A is a diagram illustrating a cross-sectional configuration of the sealed object 80. FIG. 10B is a view showing the upper surface of the inspection medium 1d. FIG. 10C is a view showing the upper surface of the sealed object 80.

  As shown in FIG. 10A, the sealed object 80 is obtained by enclosing and covering various kinds of the enclosed object 22 and the inspection medium 1d in an envelope 40 and sealing them.

  As shown in FIGS. 10A and 10B, in the inspection medium 1d, the image information 13 is provided on the base material 11, and the infrared light emitting layer 15 is provided on the image information 13. . In the present embodiment, it is assumed that the inclusion 22 is various invoices and application forms for each individual, the image information 13 is associated with this, and the name of the destination of the inclusion 22 is recorded with a barcode.

  The envelope 40 is formed of a paper material, and is a layer that transmits infrared rays and absorbs or reflects visible light, whereby the image information 13 is invisible to the naked eye. However, in this case, the material of the envelope 40 is not limited to paper. Furthermore, in this embodiment, as shown in FIGS. 10A and 10C, the name of the destination of the sealed object 80 is displayed on the surface of the envelope 40 with OCR characters that can be read under visible light as the image information 45. Is formed.

  Also in this embodiment, the image information 13 can be read after the authenticity determination of the inspection medium 1d is performed in the same manner as in the first embodiment. Similarly to the fourth embodiment, a reading device (not shown) for reading the image information 45 is connected to the information processing device 55, and the read image information 13 and the reading result of the image information 45 are collated. It can be inspected whether the inclusion 22 and its destination coincide.

  Next, a result obtained by examining the information recording medium 1 according to the first embodiment of the present invention will be described as an example. Note that the present invention is not limited to this.

[True information recording medium 1]
<Creation of fluorescent material>
As a fluorescent material for forming the infrared light emitting layer 15, two kinds of infrared excitation / infrared light emitting pigments “SG-YS (manufactured by Nemoto Special Chemical Co.)” and “IRS-L (Nemoto Special Chemical Co., Ltd.) each containing different phosphors are used. Made in water-based ink. The blending weight ratio is shown below.
SG-YS (manufactured by Nemoto Special Chemical Co., Ltd.): 2.5%
IRS-L (manufactured by Nemoto Special Chemical): 2.5%
Water-soluble acrylic resin: 20.0%
Water: 74.0%
Alcohol solvent: 0.5%
Dispersant: 0.5%

<Formation of image information 13>
An electrophotographic printer, Apeos Port-II C4300, printed a JAN code using black toner containing carbon black using A4 plain paper as the base material 11.

<Formation of infrared light emitting layer 15>
The fluorescent material described above was applied on the substrate 11 on which the image information 13 was printed so as to cover the image information 13. For application, SV91 manufactured by Sanei Tech Co., Ltd. was used, and after application, it was dried for 10 minutes with a dryer at 45 ° C.

<Infrared transmission / visible light reflection / formation of absorption layer 17>
Black ink was offset printed on the infrared light emitting layer 15 so as to cover the image information 13. As the black ink, an ink that transmits infrared rays and does not contain a carbon black pigment, which is prepared by mixing cyan, magenta, and yellow pigments was used.

<Reader 50>
An infrared irradiation device 51 that emits infrared light having a peak wavelength of about 810 nm as excitation light is used. As the infrared light receiving device 53, filters 63, 65, and 67 are attached to infrared cameras 73, 75, and 77, respectively. The camera 73 is configured to receive infrared rays in a wavelength region centered on 900 nm, the infrared camera 75 is 925 nm, and the infrared camera 77 is 1000 nm. An infrared light receiving sensor was used as the infrared camera, and the received light data was analyzed by the information processing device 55.

<Scanning result>
FIG. 11A is a diagram showing an emission spectrum of the infrared light emitting layer 15. This spectral distribution is the same as that described in FIG. 2C and the like. As a result of analyzing the received light data by the information processing device 55, the infrared cameras 73 and 77 detect infrared rays, and the infrared camera 75 does not transmit infrared rays. Since it was detected, it corresponds to Case 3 in FIG. 6 and the information recording medium was determined to be true.

In addition, when the image information 13 based on the amount of infrared light received by the infrared camera 77 is displayed on the display unit 104 of the information processing device 55, a JAN code that cannot be visually recognized from the surface of the information recording medium 1 is displayed. The JAN code part was displayed in black and the other parts were displayed in white.
The JAN code can be authenticated by performing image processing on the image information 13. That is, authentication of the image information 13 made invisible by the infrared transmission / visible light reflection / absorption layer 17 was possible.

[Fake information recording medium (1)]
An information recording medium was prepared using a material different from the true information recording medium 1 for the phosphor of the infrared light emitting layer 15.

<Fluorescent material>
As a fluorescent material for forming the infrared light emitting layer 15, an infrared excitation / infrared light emitting pigment “IRS-L (manufactured by Nemoto Special Chemical Co., Ltd.)” was used as a water-based ink. The blending weight ratio is shown below.
IRS-L (manufactured by Nemoto Special Chemical): 5.0%
Water-soluble acrylic resin: 20.0%
Water: 74.0%
Alcohol solvent: 0.5%
Dispersant: 0.5%

  The formation method of the image information 13, the infrared light emitting layer 15, and the infrared transmission / visible light reflection / absorption layer 17 was the same as that of the true information recording medium 1. Then, the reading was performed using the reading device 50 in the same manner as the true information recording medium 1.

<Scanning result>
FIG. 11B is a diagram showing an emission spectrum of the infrared light emitting layer 15. As a result of analyzing the received light data by the information processing device 55, the infrared camera 73 detects infrared rays, and the infrared cameras 75 and 77 do not detect infrared rays, which corresponds to case 4 in FIG. It was judged. In addition, although it tried to display the image information 13 based on the amount of received infrared rays in the infrared camera 77, nothing was displayed.

[Fake information recording medium (2)]
An information recording medium was prepared using a material having a composition different from that of the true information recording medium 1 and the fake information recording medium (1) as the fluorescent material of the infrared light emitting layer 15.

<Fluorescent material>
As a fluorescent material for forming the infrared light emitting layer 15, an infrared excitation / infrared light emitting pigment “SG-YS (manufactured by Nemoto Special Chemical)” was used as a water-based ink. The blending weight ratio is shown below.
SG-YS (manufactured by Nemoto Special Chemical): 5.0%
Water-soluble acrylic resin: 20.0%
Water: 74.0%
Alcohol solvent: 0.5%
Dispersant: 0.5%

  The formation method of the image information 13, the infrared light emitting layer 15, and the infrared transmission / visible light reflection / absorption layer 17 was the same as that of the true information recording medium 1. Then, the reading was performed using the reading device 50 in the same manner as the true information recording medium 1.

<Scanning result>
FIG. 11C is a diagram showing an emission spectrum of the infrared light emitting layer 15. As a result of analyzing the received light data by the information processing device 55, the infrared cameras 73 and 75 do not detect infrared rays, the infrared camera 77 detects infrared rays, which corresponds to case 6 in FIG. 6, and the information recording medium is determined to be false. .

[Fake information recording medium (3)]
An information recording medium was prepared using a material having a composition different from that of the true information recording medium 1 and the fake information recording mediums (1) and (2) for the fluorescent material of the infrared light emitting layer 15.

<Fluorescent material>
As a fluorescent material for forming the infrared light emitting layer 15, two kinds of infrared excitation / infrared light emitting pigments "IR900 (manufactured by Nemoto Special Chemical Co.)" and "SG-YS (manufactured by Nemoto Special Chemical Co., Ltd.)" containing different phosphors, respectively. Was used as a water-based ink. The blending weight ratio is shown below.
IR900 (manufactured by Nemoto Special Chemical): 2.5%
SG-YS (manufactured by Nemoto Special Chemical Co., Ltd.): 2.5%
Water-soluble acrylic resin: 20.0%
Water: 74.0%
Alcohol solvent: 0.5%
Dispersant: 0.5%

  The formation method of the image information 13, the infrared light emitting layer 15, and the infrared transmission / visible light reflection / absorption layer 17 was the same as that of the true information recording medium 1. Then, the reading was performed using the reading device 50 in the same manner as the true information recording medium 1.

<Scanning result>
FIG. 11 (d) is a diagram showing an emission spectrum of the infrared light emitting layer 15. As a result of analyzing the received light data by the information processing device 55, the infrared cameras 73, 75, 77 detected infrared rays. This corresponds to case 1 in FIG. 6, and the information recording medium was determined to be false.

  As described above, the fake information recording media (1) to (3) having the infrared light emitting layer 15 using a fluorescent material different from that of the true information recording medium 1 are analyzed by analyzing the spectrum distribution. It was determined that Note that the emission spectra of the infrared light emitting layers 15 of the fake information recording media (1) to (3) are different from the distribution described with reference to FIG. , No wavelength portion 27 lower than the emission intensity threshold 25 by a width 26 corresponding to 30% of the emission intensity at the peak wavelength 20 does not occur between the wavelength ranges 31 and 35. .

  The preferred embodiments of the present invention have been described above with reference to the accompanying drawings, but the present invention is not limited to such examples. It will be apparent to those skilled in the art that various changes or modifications can be conceived within the scope of the technical idea disclosed in the present application, and these naturally belong to the technical scope of the present invention. Understood.

1, 1a, 1b: Information recording medium 1c: Lottery 1d: Inspection medium 11: Base material 13: Image information 15: Infrared light emitting layer 17: Infrared transmission / visible light reflection / absorption layer 21, 23: Peak wavelengths 31, 35 : Peak region 33: Valley region 50: Reading device 51: Infrared irradiation device 53: Infrared light receiving device 55: Information processing devices 73, 75, 77: Infrared camera

Claims (11)

An information recording medium in which an infrared light emitting layer that emits infrared light having a peak wavelength different from that of excitation light is excited or excited by infrared light on or below image information that absorbs infrared light formed on a substrate. On the other hand, an irradiation step of irradiating excitation light;
A light receiving step for receiving infrared light emitted from the infrared light emitting layer through a filter that cuts a peak wavelength of the excitation light;
Authenticity determination step for determining the authenticity of the information recording medium by analysis of infrared light received in the light receiving step;
A reading step of reading the image information from the infrared light received in the light receiving step when the information recording medium is determined to be true in the authenticity determination step;
A method for reading an information recording medium, comprising: In the light receiving step, for each of a plurality of wavelength ranges of the infrared light emitted by the infrared light emitting layer, infrared light is received;
2. The information recording medium reading method according to claim 1, wherein in the authenticity determination step, the authenticity of the information recording medium is determined based on the amount of infrared light received in the plurality of wavelength regions.   The infrared light emitted by the infrared light emitting layer is a peak of infrared light emitted by the infrared light emitting layer between the first wavelength region and the second wavelength region where the light emission intensity is a value equal to or greater than a predetermined light emission intensity threshold value. 3. The method for reading an information recording medium according to claim 1, wherein the information recording medium has a wavelength at which the emission intensity is at least 30% of the emission intensity of the wavelength and lower than the emission intensity threshold value. In the authenticity determination step, at least an infrared light reception amount in the first wavelength range determined according to the emission intensity threshold is equal to or greater than a first predetermined value, the first wavelength range, and the light emission when the amount of light received by the infrared third wavelength region is between the second wavelength range determined according to the intensity threshold value is less than the second predetermined value, determines that the true the information recording medium The method for reading an information recording medium according to claim 3.   5. The information recording medium reading method according to claim 4, wherein the reading step reads the image information based on infrared rays in the second wavelength band. In the authenticity determination step, the amount of infrared light received in the first wavelength range determined according to the emission intensity threshold is greater than or equal to a first predetermined value and the first wavelength range and the emission intensity. amount of received infrared third wavelength region is less than a second predetermined value which is between the second wavelength range determined according to threshold, and the light receiving amount of the infrared of the second wavelength region first 6. The method of reading an information recording medium according to claim 3, wherein the information recording medium is determined to be true when the value is equal to or greater than a predetermined value of 3. Above or below the image information that absorbs infrared rays formed on the substrate,
An infrared light emitting layer that emits infrared light that is excited by infrared excitation light and has a peak wavelength different from that of excitation light is formed.
The infrared light emitted by the infrared light emitting layer is a peak of infrared light emitted by the infrared light emitting layer between the first wavelength region and the second wavelength region where the light emission intensity is a value equal to or greater than a predetermined light emission intensity threshold value. An information recording medium having a wavelength at which the emission intensity is at least 30% of the emission intensity of the wavelength and lower than the emission intensity threshold value.   8. The information recording medium according to claim 7, wherein the infrared light emitting layer includes a plurality of types of phosphors that emit infrared light having different peak wavelengths when excited with the same excitation light.   The information recording medium according to claim 7, wherein the infrared light emitting layer is formed on the image information.   The information recording medium according to claim 7 or 8, wherein the image information is formed on the infrared light emitting layer.   The information recording medium according to any one of claims 7 to 10, wherein the image information is covered with a material that transmits infrared rays and reflects or absorbs visible light.

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