KR102660115B1 - Authentification device and method for security pattern - Google Patents

Abstract

According to the present invention, a plurality of image frames are obtained by sequentially photographing a security pattern formed including a special material, and an image frame number at which the security pattern image is not detected is calculated from the time the excitation light is turned off, thereby authenticating the security pattern. It has the effect of performing all recognition.

Description

Security pattern authentication device and method {AUTHENTIFICATION DEVICE AND METHOD FOR SECURITY PATTERN}

The present invention relates to a security pattern authentication device and method.

Security patterns such as barcodes or QR codes are used to prevent forgery and alteration of documents or products, authenticate products, and track history. Information about the product is stored in the security pattern, and functions such as product authentication and history tracking can be implemented by recognizing it with a device such as a barcode reader. Security patterns are usually printed on the container or packaging of the product.

Meanwhile, security patterns are relatively easy to forge and falsify, and for ordinary consumers, there is a problem in that it is difficult to know whether the pattern has been forged or altered. Therefore, an authentication device and method that can identify the authenticity of a security pattern is required.

There is a known technology for implementing a product authentication code that is difficult to replicate by including a fluorescent material in the security pattern, but this technology has the disadvantage of requiring a separate device for identifying the authenticity of the security pattern and a device for recognizing the security pattern.

KR 10-2017-0018672 A (2017.02.20)

The present invention was conceived to solve the problems of the prior art, and specifically, its purpose is to provide a device and method that can perform both authentication and recognition of security patterns.

The object of the present invention is not limited to the above, and other objects and advantages of the present invention that are not mentioned can be understood by the following description.

A security pattern authentication method according to an embodiment of the present invention includes the steps of irradiating excitation light to a security pattern formed including a special material that absorbs excitation light of a first wavelength and emits light of a second wavelength, here A step of sequentially acquiring a plurality of image frames by continuously photographing the security pattern with an imaging device from the point of turning off the light, a step of calculating an invisible image frame number among the plurality of sequentially acquired frames, and the calculated invisible image frame. It includes a step of comparing the number with a pre-stored reference number, and a step of authenticating the product as a genuine product if the calculated invisible image frame number is the same as the reference number and not certifying the product as a genuine product if it is not the same.

At this time, the non-visible image frame may be the first image frame in which the luminance value calculated at one or more specific positions of the acquired image frame is smaller than the reference value.

In this case, the specific location includes at least a first location and a second location, and the first location and the second location may contain different concentrations or different types of special substances.

As another variation, the security pattern may be a one-dimensional or two-dimensional barcode.

As another variation, the special material may be an invisible material.

Alternatively, the second wavelength may belong to the infrared wavelength range.

As another variation, multiple image frames may be acquired by multiple imaging devices. At this time, the plurality of imaging devices may be operated with time differences.

As another variation, the invisible image frame may be the first image frame in which information stored in the security pattern cannot be read from the security pattern image of the image frame acquired by the imaging device.

A security pattern authentication device according to an embodiment of the present invention is an authentication device for authenticating a security pattern formed including a special material that absorbs excitation light of a first wavelength and emits light of a second wavelength. A light source unit that irradiates excitation light to the pattern, an imaging device unit that sequentially acquires a plurality of image frames by continuously photographing the security pattern from the point of turning off the excitation light, and invisibility among the plurality of frames sequentially acquired by the imaging device unit. A processing unit that calculates the image frame number, a judgment unit that compares the invisible image frame number calculated by the processing unit with a pre-stored reference number and judges it as a genuine product if it is the same, and does not judge it as a genuine product if it is not the same, and a light source unit and an imaging device unit. Includes a control unit that controls operations.

At this time, the imaging device unit may include a plurality of imaging devices, and the plurality of imaging devices may be operated with a time difference from each other.

As another modified example, the processing unit is an image processing unit, and the image processing unit calculates the luminance value at one or more specific positions of the image frame acquired from the imaging device, and determines the number of the first image frame where the calculated luminance value is smaller than the reference value to be invisible. It can be calculated using the image frame number.

At this time, the specific location includes at least a first location and a second location, and the first location and the second location may include different concentrations or different types of special substances.

As another modification, the processing unit is a code recognition unit, the code recognition unit reads the information stored in the security pattern from the security pattern image of the image frame acquired from the imaging device, and the code recognition unit is the first image frame in which information cannot be read. The number can be calculated as an invisible image frame number.

According to the present invention, a plurality of image frames are obtained by sequentially photographing a security pattern formed including a special material, and an image frame number at which the security pattern image is not detected is calculated from the time the excitation light is turned off, thereby authenticating the security pattern. It has the effect of performing all recognition.

However, the effects of the present invention are not limited to those mentioned above, and other effects not mentioned will be clearly understood by those skilled in the art from the description below.

1 is a diagram illustrating a security product including a security pattern according to the present invention.
Figure 2 is a conceptual diagram for explaining the security pattern authentication method according to the present invention.
Figure 3 is a flowchart of a security pattern authentication method according to the present invention.
Figure 4 is a block diagram of a security pattern authentication device according to the present invention.
Figures 5 and 6 are diagrams for explaining a security pattern authentication process according to an embodiment of continuous shooting with a single camera.
Figures 7 and 8 are diagrams for explaining a security pattern authentication process according to an embodiment of continuous shooting with multiple cameras.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings, but the present invention is not limited or restricted by the embodiments.

In describing the present invention, if it is determined that a detailed description of related known technologies may obscure the gist of the present invention, the detailed description will be omitted. In addition, numbers (eg, first, second, etc.) used in the description of this specification are merely identifiers to distinguish one component from another component. In describing various embodiments of the present invention, the same names and the same reference numerals will be given to corresponding components.

Figure 1 is a diagram illustrating a security product 200 including a security pattern 100 according to the present invention. The security product 200 may be various security documents or products. The security pattern 100 is a code containing information related to the security product 200, and may be a one-dimensional or two-dimensional barcode, but is not limited thereto. The security pattern 100 may be printed directly on the surface of the security product 200 or may be produced in the form of a sticker and attached to the surface of the security product 200. The security pattern 100 can be read using a recognition device. The recognition device may include an image acquisition device for acquiring an image of the security pattern 100, such as an imaging device such as a camera.

The security pattern 100 is formed including a special material. For example, the security pattern 100 may be printed with ink containing a special substance.

A special material refers to a material that emits emission light including a second wavelength when incident light including a first wavelength is irradiated, and various materials may be used depending on the first and second wavelengths. For example, special substances are invisible substances that cannot be observed with the naked eye under general visible light, and substances with the following general formula can be used.

General formula (1); Ba _1-x SnA _x O ₃ (0<x<0.4, A is Li or Na)

General formula (2); CaMoO ₄ :M (M is one or two or more lanthanide metal ions selected from the group consisting of Nd ³⁺ , Yb ³⁺ and Er ³⁺ )

General formula (3); Y ₂ SiV ₂ O ₁₀ :Nd ³⁺ and Er ³⁺

General formula (4); Y ₂ O ₃ :Yb and Ho

General formula (5); Y ₂ O ₃ :Yb and Tm

General formula (6); Y ₂ O ₃ :Yb and Er

Here, the material of General Formula (1) is a material that emits light in the infrared wavelength range for incident light in the ultraviolet wavelength range, and the material of General Formula (2) is a material that emits light in the infrared wavelength range for incident light in the visible wavelength range. It is a substance, and the substance of general formula (3) is a substance that emits light in the infrared wavelength range in response to incident light in the ultraviolet or visible wavelength range. In addition, the materials of general formulas (4), (5), and (6) are up-conversion materials that emit light in the infrared and visible wavelength ranges with respect to incident light in the infrared wavelength range.

In embodiments of the present invention, the first wavelength may be in the ultraviolet wavelength range, but is not limited thereto. For example, the first wavelength may be a visible light wavelength range or an infrared (including near-infrared and mid-infrared) wavelength range.

In embodiments of the present invention, the second wavelength may be a visible light wavelength range or an infrared wavelength range, particularly a near-infrared wavelength range. The infrared wavelength range cannot be detected with the naked eye, so it is impossible to tell whether special substances are included unless an infrared detection device is used. Additionally, in the case of special substances that emit infrared rays, abundant light emission can be obtained even with a relatively small amount, making it cost-effective. It can also be advantageous.

Figure 2 is a conceptual diagram for explaining the security pattern authentication method according to the present invention.

Referring to Figure 2, since the security pattern 100 according to the present invention is formed including a special material 101, when an image of the emission light of the second wavelength is obtained after irradiating excitation light containing the first wavelength, the security pattern You can check (100). At this time, even if the excitation light is turned off, the emission light does not disappear immediately, and an afterglow remains for a certain period of time. That is, as illustrated in FIG. 2, if a plurality of image frames are acquired sequentially at regular time intervals from the point when the excitation light is turned off, the first image frame at which the excitation light is turned off provides clear security. A pattern image is acquired, but the security pattern image gradually becomes fainter from the second image frame, and the security pattern image is no longer detected in the fifth image frame.

Meanwhile, since the speed at which the afterglow disappears is a unique characteristic of special materials, the first image frame number at which the security pattern 100 is no longer detected varies depending on the type and content of the special material included in the security pattern 100. do. The present invention uses this principle for genuine product authentication, by comparing the number of the first image frame (invisible image frame) in which the security pattern is no longer detected from the time the excitation light is turned off with a pre-stored reference number, It is characterized by determining the authenticity of the security pattern 100. At this time, continuous image frame acquisition can utilize the continuous shooting function provided in an imaging device such as a camera.

Figure 3 is a flowchart of a security pattern authentication method according to the present invention. Referring to Figure 3, the security pattern authentication method according to the present invention includes the steps of irradiating excitation light (step S11), acquiring a plurality of image frames (step S12), and calculating an invisible image frame number (step S11). Step S13) and a step of determining the authenticity of the product using the standard number (Step S14).

The step of irradiating excitation light (step S11) is a step of irradiating excitation light including a first wavelength to excite the special material to the security pattern 100 formed including the special material. For example, if the special material is a light-emitting material of general formula (1) that emits light in the infrared wavelength range by excitation light in the ultraviolet wavelength range, the excitation light containing the first wavelength in the ultraviolet wavelength range is used as a security pattern. (100) may be an investigation step.

When the excitation light is irradiated, the special material is excited by the light of the first wavelength included in the excitation light and may emit emission light including the second wavelength.

The next step is to acquire a plurality of image frames, using an image acquisition device capable of detecting light of the second wavelength to acquire security pattern images at regular time intervals from the time the excitation light is turned off (S12 step). As an image acquisition device, an imaging device such as a camera equipped with a continuous shooting function can be used.

Next, the number of the invisible image frame among the plurality of image frames acquired in step S12 is calculated (step S13). The non-visible image frame refers to the first image frame in which the security pattern is no longer detected from the time the excitation light is turned off, and various standards can be set to determine the non-visible image frame.

For example, according to one embodiment of the present invention, the first image frame in which the luminance value calculated at one or more specific positions among the acquired security pattern images is smaller than the reference value may be defined as an invisible image frame. That is, a method of comparing the luminance of a specific position 102 (see FIG. 2) of the security pattern 100 with a reference value can be used through a method of image processing the acquired security pattern image. When the excitation light is turned off, the luminance value of the specific location 102 decreases over time, so it can be confirmed whether the special substance is included by comparing it with the reference value.

The specific location 102 may be set in multiple numbers. That is, different first and second positions among the security patterns 100 are set as specific positions 102, and the luminance values at the first and second positions are compared with the reference value and both values are below the reference value. The first image frame can be determined as an invisible image frame. If the luminance value at the first position is below the reference value, while the luminance value at the second location is above the reference value, step S12 may be repeated or the product may be determined to be non-genuine. Through this method, a more reliable judgment of authenticity may be possible compared to using one specific location.

Meanwhile, it is also possible to include different concentrations of special substances or different types of special substances in the first and second positions through multiple printing processes. In this case, the reference values at the first and second positions may be set differently. That is, the first image frame in which the luminance value at the first position is below the first reference value and the luminance value at the second location is below the second reference value may be determined as an invisible image frame. If the luminance value at the first location is below the first reference value, while the luminance value at the second location is above the second reference value, step S12 may be repeated or the product may be determined to be non-genuine. In this way, it is possible to provide a high anti-counterfeiting effect by varying the concentration of the special substance or the type of the special substance at the specific location 102.

According to another embodiment of the present invention, the first image frame in which information stored in the security pattern cannot be read from the acquired security pattern image can be defined as an invisible image frame. In other words, if the security pattern image is clearly acquired, the code can be interpreted and the stored information can be easily read. However, if the security pattern image is blurred, reading may become increasingly difficult. For example, taking the conceptual diagram of FIG. 2 as an example, while security pattern reading is possible up to the fourth image frame after the excitation light is turned off, security pattern reading may become difficult in the fifth image frame. In this case, the 5th image frame can be determined as an invisible image frame.

After calculating the invisible image frame number, the authenticity of the product is determined using the standard number (step S14). The standard number is a pre-stored number related to a special substance included in the security pattern. If it is a genuine product, the invisible image frame number and the standard number must be the same. In other words, if the invisible image frame number calculated through steps S11 to S13 is the same as the pre-stored reference number, it is authenticated as a genuine product, and if it is not the same, it is not certified as a genuine product, thereby determining the authenticity of the product.

FIG. 4 is a block diagram of a security pattern authentication device that can be used to perform the security pattern authentication method of FIG. 3. Referring to FIG. 4, the authentication device according to an embodiment of the present invention may include a light source unit 300, an imaging device unit 301, a processing unit 302, a determination unit 303, and a control unit 304.

The light source unit 300 is configured to irradiate excitation light including a first wavelength and includes a light source capable of generating light including the first wavelength, and may be a light source in the form of a lamp or LED, for example. When the authentication device is a portable terminal such as a smartphone, the light source unit 300 may be a flash provided in the portable terminal.

The imaging device unit 301 is configured to continuously acquire images of the security pattern 100 at regular time intervals, and an example thereof may include a camera. Since light of the second wavelength must be detected, if the second wavelength is in the infrared wavelength range, the imaging device unit 301 may be an infrared camera. When the authentication device is a portable terminal such as a smartphone, the imaging device unit 301 may be a camera provided in the portable terminal.

The processing unit 302 receives a plurality of image frames acquired from the imaging device unit 301 and calculates an invisible image frame number, and can be configured in various ways depending on the method of determining the invisible image frame. For example, when the first image frame in which the luminance value at a specific location of the acquired security pattern image is smaller than the reference value is determined to be an invisible image frame, the processing unit 302 image-processes the security pattern image to determine the luminance value at a specific location of the acquired security pattern image. It may be an image processing unit capable of calculating a luminance value. Alternatively, if the first image frame in which the information stored in the security pattern cannot be read from the acquired security pattern image is determined to be an invisible image frame, the processing unit 302 has a function of reading the security pattern and extracting the stored information. It may be a code recognition unit.

The determination unit 303 compares the invisible image frame number calculated by the processing unit 302 with a pre-stored reference number and determines it as a genuine product if it is the same, and does not judge it as a genuine product if it is not the same. For this purpose, the determination unit 303 may include a memory in which a reference number is stored.

The control unit 304 is configured to control the operation of each functional block, such as the light source unit and the imaging device unit. The control unit can control the ON/OFF operation of the light source unit and, in conjunction with this, control the continuous shooting operation of the imaging device unit. That is, the control unit controls the light source unit to be turned on for a certain period of time and then turned off, and in conjunction with this, the imaging device continuously acquires a plurality of security pattern image frames at regular time intervals from the time the light source unit is turned off. The wealth can be operated.

Meanwhile, the security pattern authentication device according to the present invention may further include a code recognition unit for reading the security pattern. At this time, the control unit 304 can control the code recognition unit to read the security pattern and perform an operation according to the read information only when the determination unit 303 determines the product to be genuine. In an embodiment in which the processing unit 302 includes a code recognition unit, a separate code recognition unit may not be needed.

Additionally, the imaging device unit 301 may include a plurality of imaging devices. When installing multiple imaging devices to sequentially acquire multiple image frames, it is possible to continuously acquire multiple image frames at shorter time intervals than sequentially acquiring multiple image frames with a single imaging device. , this may enable more precise determination of authenticity. For this purpose, it is preferable that the plurality of imaging devices operate with a time difference from each other. In this case, the starting point of imaging for each of the plurality of imaging devices is sequentially between the first and second frames of the leading imaging device and the first frame of the succeeding imaging device. It is advisable to get this started.

Comparing the case of continuous shooting with a single camera as shown in Figures 5 and 6 and the case of continuous shooting with multiple cameras as shown in Figures 7 and 8, the case of continuous shooting as shown in Figures 5 and 6 While the spacing between image frames is wide, lower accuracy can be obtained. On the other hand, when continuous shooting is performed with a plurality of cameras as shown in FIGS. 7 and 8, higher accuracy can be obtained due to the narrow spacing between consecutive image frames. In this way, by continuously shooting with a plurality of imaging devices, tighter image frames can be acquired, which allows more accurate determination of the authenticity of special substances included in the security pattern.

Continuous shooting using multiple cameras as shown in FIG. 7 can use multiple cameras included in a portable terminal such as a smartphone. At this time, the control unit 304 can control the plurality of cameras to operate continuously with a time difference from the time the light source unit 300 is turned off.

Although the above description has been made with reference to the limited examples and drawings, these are only examples, and it will be apparent to those skilled in the art that various modifications and implementations are possible within the scope of the technical idea of the present invention. For example, each embodiment may be implemented in whole or in part in selective combination. Therefore, the scope of protection of the present invention should be determined by the description of the patent claims and their equivalent scope.

100: Security pattern
101: Special substances
102: Specific location
200: Security products
300: Light source unit
301: Imaging device unit
302: Processing unit
303: Judgment unit
304: control unit

Claims (15)

Irradiating excitation light to a security pattern formed including a special material that absorbs excitation light of a first wavelength and emits light of a second wavelength;
sequentially acquiring a plurality of image frames by sequentially photographing the security pattern with an imaging device from the point of turning off the excitation light;
calculating an invisible image frame number among the plurality of sequentially acquired image frames;
Comparing the calculated invisible image frame number with a pre-stored reference number; and
certifying the product as a genuine product if the calculated invisible image frame number is the same as the reference number and not certifying the product as a genuine product if the calculated non-visible image frame number is not the same as the reference number;
Including,
The invisible image frame is the first image frame in which the code recognition unit, which functions to read the security pattern and extract the stored information, cannot read the information stored in the security pattern from the security pattern image of the image frame acquired by the imaging device. and
The step of calculating the invisible image frame number includes the code recognition unit calculating the number of the first image frame in which the information stored in the security pattern cannot be read among a plurality of image frames sequentially acquired from the imaging device, thereby determining the number of the security pattern. A security pattern authentication method characterized in that it is a step performed without comparing the luminance value of a specific location with a reference value. delete delete According to paragraph 1,
A security pattern authentication method, wherein the security pattern is a one-dimensional or two-dimensional barcode. According to paragraph 1,
A security pattern authentication method, wherein the special material is an invisible material. According to paragraph 1,
A security pattern authentication method, characterized in that the second wavelength belongs to the infrared wavelength range. According to paragraph 1,
A security pattern authentication method, characterized in that the plurality of image frames are acquired by a plurality of imaging devices. In clause 7,
A security pattern authentication method, characterized in that the plurality of imaging devices are operated with a time difference from each other. delete An authentication device for authenticating a security pattern formed including a special material that absorbs excitation light of a first wavelength and emits light of a second wavelength, comprising:
a light source unit that radiates excitation light to the security pattern;
an imaging device unit sequentially acquiring a plurality of image frames by sequentially photographing the security pattern from the time the excitation light is turned off;
a processing unit that calculates an invisible image frame number among a plurality of image frames sequentially acquired by the imaging device unit;
a determination unit that compares the non-visible image frame number calculated by the processing unit with a pre-stored reference number and determines the non-visible image frame number as genuine if the number is the same; and
a control unit that controls operations of the light source unit and the imaging device unit;
Including,
The processing unit is a code recognition unit,
The code recognition unit reads information stored in the security pattern from the security pattern image of the image frame acquired from the imaging device,
The code recognition unit calculates the first image frame number at which information cannot be read as an invisible image frame number, thereby calculating the invisible image frame number without comparing the luminance value of a specific position of the security pattern with a reference value. A security pattern authentication device that According to clause 10,
A security pattern authentication device, wherein the imaging device unit includes a plurality of imaging devices. According to clause 11,
A security pattern authentication device, characterized in that the plurality of imaging devices are operated with a time difference from each other. delete delete delete

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