RU2625253C1 - System for determining authenticity of documents and money marks - Google Patents

Abstract

FIELD: physics.

SUBSTANCE: system for determining the authenticity of banknotes and documents includes a portable set-top box connected to a smartphone, in which data on anti-stoke marks of various types of banknotes are downloaded. The specified data are transferred to the console. The prefix is made with the possibility of comparing the data received from the smartphone with the data obtained, when measuring the response of the anti-stoke marks of the banknote being checked. The radiation frequency of the infra-red LED of the set-top box is set at a multiple of 10 Hz.

EFFECT: increasing the sensitivity of the system, reducing the power of infrared radiation, increasing safety in operation and reducing the time for determining the authenticity of banknotes or documents.

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Description

The invention relates to the field of authentication of banknotes and documents endowed with protective anti-Stokes tags with various characteristics.

The prior art system for recognizing documents (see RU 2321065, CL G07D 7/12, publ. 2008).

The known system is designed to recognize documents equipped with a security tag containing a substance that is excited when light falls on it. Moreover, this system includes a light source for exciting the specified substance and a node for detecting the light emitted by the excited substance marks the recognized document, and the specified node is associated with an electronic processing system containing a microprocessor.

The specified node for detecting light is configured to analyze the light intensity of different wavelengths by comparing them with a set of values stored in the microprocessor memory, in order to determine whether the recognized document is genuine or fake.

Since the marks applied to a document or banknotes protecting them from counterfeiting by the human eye are visually invisible and, as a rule, are located in undefined sections of various documents and banknotes, in the compact (portable) version of this system manufacturing, with no recognition sensor, the process of determining authenticity will become more complicated, since the user will need to intuitively select a section with a protective mark, which should be affected by a monochromatic light source, which in turn l increases the determination time of a genuine or fake test object.

In addition, the well-known document recognition system uses a monochromatic light source, mainly a laser, which can harm human health, and in some cases may require mandatory certification of equipment that slows down and complicates the mass production of known recognition systems.

A detector is known in the art for detecting the presence / absence and / or nature of a security tag (see RU 2435223, CL G07D 7/12, publ. 2011).

The known detector comprises means for emitting radiation, means for detecting radiation, a section for placing the product.

Moreover, the area for placing the product contains a leveling means, ensuring alignment of the product with the emitting means.

In addition to the possibility of detecting the presence, absence and nature of the protective mark, this detector is technically endowed with a wide range of functionally transforming abilities that increase its usability, in particular, realized due to the fact that the alignment means ensures alignment of the product with the emitting means, the first and second parts of the housing made with the ability to move relative to each other, the housing is equipped with a means of detecting rapprochement and displaying means, the first and the second part of the housing is pivotally connected and pivotally moved between the first and second configurations, etc. This multifunctionality is associated with an increased likelihood of transient and frequent breakdowns, since it contains a significant number of interacting and interconnected elements that perform various mechanical movements, which in turn significantly reduces the degree of product reliability during continuous operation.

The closest analogue of the invention is a viewing device for verifying the authenticity of banknotes and securities (see RU 122192, CL G07D 7/12, publ. 2012).

A known viewing device for verifying the authenticity of banknotes and securities is made in the form of a portable set-top box, configured to connect to a computer containing a microcontroller for processing incoming signals.

The presence in the known design of the viewing device of a digital video camera significantly slows down the process of recognizing documents, and also leads to an increase in the dimensions of the device, reducing its compactness.

The present invention solves the technical problem (task) of creating a reliable effective and at the same time compact small-sized system for determining the authenticity of banknotes and documents, simple to use and easy to move, as well as having high technical and operational characteristics.

The technical result of the invention, which is objectively manifested in the course of its use, is the implementation of the indicated purpose of the invention, which consists in creating a reliable efficient, but compact (small-sized) system for determining the authenticity of banknotes and documents, as well as increasing the sensitivity of the system, reducing the power of infrared radiation , increasing safety during operation and reducing the time to determine the authenticity of banknotes or documents.

The specified technical result that solves this technical problem (task) is achieved due to the fact that the system for determining the authenticity of banknotes and documents includes a portable set-top box equipped with a microcontroller, made interconnected with a computer, and the computer is made in the form of a portable electronic device containing a display and a microprocessor made with the possibility of assessing the radiation intensity of anti-Stokes tags of banknotes of various denominations, as well as various documents examined and sending corresponding a corresponding electrical information signal containing information about the radiation intensity of anti-Stokes labels in the aforementioned microcontroller equipped with an infrared LED connected to it and a photodetector configured to receive optical signals in the infrared range and analyze the received optical signals after the said infrared LED is turned off during the period after which the phosphor afterglow , whose duration is from one hundred to ten thousand microseconds, at this frequency of emission of light signals of the infrared LED, receiving a response from them and sending them to the microcontroller is set to not a multiple of 10 Hz, providing the selection of a useful signal against the background of noise interference with its subsequent digitization and disclosure.

The essence of the proposed technical solution is as follows.

At the current time, the anti-Stokes tag is a reliable sign of the authenticity of the document, since due to its extremely high complexity it is practically impossible to fake it. The proposed authentication system detects an anti-Stokes tag on banknotes and documents.

The hardware of the portable set-top box is equipped with a unique anti-Stokes paint sensor, namely a low-power infrared LED, which does not harm human health.

In existing laser detectors that detect the presence or absence of an anti-Stokes tag, it is necessary to observe the green glow of the anti-Stokes tag, and this is only possible when creating a darkened area in the device, since the green response is very dull and difficult to distinguish, and in the proposed authentication system a microcontroller for processing and control the incoming electrical information signals are automatically determined by the response of the anti-Stokes label using a photodetector. Thus, the anti-Stokes tag is detected with greater reliability, no dimming is required.

The anti-Stokes label implies that the emitted radiation goes into visible, usually green, as it is actually fixed, however, the essence of the proposed system is that there is some “spurious” phenomenon, namely, if infrared radiation is turned off, the anti-Stokes label continues to glow in the infrared range for some time (luminesce). The proposed authentication system handles this “parasitic” phenomenon in its final stage. You do not need a green glow. Thanks to this technique, the sensitivity of the system is significantly higher than devices using unsafe laser radiation, and in which there is a need for independent monitoring of the presence or absence of a green response. This circumstance made it possible to reduce the power of infrared radiation to the value at which it became possible to replace the laser with an LED.

In the present invention, the frequency of scanning infrared optical signals, receiving a response from them and sending them to the microcontroller for processing incoming electrical information signals is set to not a multiple of 10 Hz. The proposed embodiment is illustrated as follows. The portable set-top box in the proposed system performs more than 10 measurements per session, where each measurement is a pulse of an infrared LED and digitization of the final afterglow of the phosphor with their subsequent averaging. Mostly the noise is concentrated in a certain spectrum (for countries with a frequency of 50 Hz, the noise is concentrated at a frequency of 100 Hz), so if you digitize a useful signal at frequencies that are not multiple of 10 Hz, the useful signal is summed in-phase, and the noise is random. Thus, the useful signal is distinguished against the background of noise interference, because the “tail” of the phosphor was the same in each dimension, and the interference developed with different phases, which is why it weakened.

As a result, the microprocessor of a portable electronic device containing a display is configured to evaluate the radiation intensity of anti-Stokes banknote labels of various denominations, as well as various documents to be examined, and to send the corresponding electrical information signal containing information about the anti-Stokes label radiation intensity to the mentioned microcontroller, increases ease of use and there is a decrease in the time of the operation of recognition of the authenticity of objects and, since the user sees a hint on the display in graphical form about the location of the mark on the document or banknote and simply brings the portable set-top box to that part of the document or banknote that the portable electronic device application indicates and displays on the display, which later receives and displays the received data on the display about whether a label is detected or not, and also receives and displays an estimate of the radiation intensity of the label on the display, simplifies and clearly demonstrates the operation of the application of the electronic device.

Due to the fact that the system consists of a portable set-top box having a microcontroller and a computer, made in the form of a portable electronic device containing a display and a microprocessor, the creation of a compact small-sized system that effectively determines the authenticity of banknotes and documents is ensured.

Thus, the above signs, technical techniques and features of the proposed system for determining the authenticity of banknotes and documents are necessary and sufficient to achieve an objectively manifest technical result consisting in the implementation of the purpose of the invention, to increase the sensitivity of the system, to reduce the power of infrared radiation, to increase safety during operation and in reducing the time for determining the authenticity of banknotes or documents, which in turn solves a technical problem ( task) reliable efficient and at the same time compact, easy to use and easy to move system for determining the authenticity of banknotes and documents with high technical and operational characteristics.

The present invention is illustrated by a specific example of implementation, which, however, is not the only possible, but at the same time demonstrates the achievement of the essential features of the specified technical result that solves the specified technical problem (task).

In FIG. 1 shows the appearance of the implementation of the invention.

In FIG. 2 presents a structural block diagram of the invention.

In FIG. Figure 3 shows an example of an application interface demonstrated on a smartphone display.

In FIG. 4 shows diagrams of the signals of the emitter and photodetector in the presence / absence of an anti-Stokes phosphor.

In FIG. 1 and 2, the following elements and means are indicated by digital positions:

1 - a system for determining the authenticity of banknotes and documents.

2 - portable set-top box;

3 - smartphone;

4 - USB connection;

5 - microcontroller for processing electrical information signals;

6 - low power infrared LED;

7 - photodetector;

8 - an examined document or a banknote.

In FIG. 3 digital numbers denote the following images, designed to inform the user:

9 - a drop-down list of types of studied objects;

10 - an expanding list of objects selected using the image (9) on the smartphone display;

11 - application menu;

12 is an image showing the true object under investigation or not;

13 is a scale illustrating radiation intensity of an anti-Stokes tag;

14 - abbreviated name of the investigated object;

15 is a view showing a user the location of the anti-Stokes tag.

In FIG. 4 letter marks indicate the following electrical information signals entering the microcontroller for processing and control of incoming electrical information signals pos. 5:

A - waveform of an infrared LED (emitter) 6;

B is the waveform at the output of the photodetector 7 in the absence of an anti-Stokes label (in shape this signal repeats the signal of the transmitter);

B is the waveform at the output of the photodetector in the presence of an anti-Stokes mark (the trailing edge of the signal is delayed due to the afterglow of the phosphor).

The proposed system for determining the authenticity of banknotes and documents pos. 1 contains a portable prefix pos. 2, having a microcontroller for processing incoming electrical information signals pos. 5 (hereinafter referred to as microcontroller 5).

Portable set-top box pos. 2 is interconnected via the USB connection pos. 4 with a computer made in the form of a smartphone pos. 3, having a display and a microprocessor.

Microprocessor smartphone pos. 3 is configured to evaluate the radiation intensity of anti-Stokes labels, as well as their location on the objects under study, i.e. The necessary information about anti-Stokes tags of various document options, as well as most of the existing world banknotes, is pre-loaded into the smartphone application.

In addition, the smartphone processor pos. 3 is configured to send an electrical information signal containing information about said radiation intensity to the microcontroller pos. 5.

Microcontroller pos. 5 contains nodes of primary and secondary signal processing (not shown in FIG.), And is also equipped with an infrared LED pos. 6 and photodetector pos. 7 containing a photodiode (not shown in FIG.).

Photodetector pos. 7 is configured to continuously receive optical signals in the infrared range and to analyze the array of received optical signals after turning off the infrared LED during the final afterglow of the phosphor, lasting several hundred microseconds.

The frequency of scanning infrared optical signals, receiving a response from them and sending them to the microcontroller pos. 5 is set not a multiple of 10 Hz, providing the selection of a useful signal against a background of noise interference with its subsequent digitization and disclosure (see Fig. 1 and Fig. 2).

In the drop-down list of types of studied objects pos. 9 includes:

- RUB (Russian ruble);

- other documents.

In the expanding list of objects pos. 10 images selected using the image 9 on the smartphone display, includes:

- for Russian rubles (banknotes of various denominations - 10 rubles, 50 rubles, 100 rubles, 500 rubles, 1000 rubles and 5000 rubles);

- for other documents (Russian passport, passport, TCP, securities, excise stamps (alcohol, tobacco), etc.).

Application menu pos. 11 contains the following items of information content:

- How to verify the authenticity of documents ?;

- with what help to verify the authenticity of documents ?;

- information about the system used (a page with help information about the system used is called up (operating instructions, precautions and other useful information);

In the image pos. 12, showing whether the object under investigation is genuine or not, a green checkmark means that the document is genuine, and a red X indicates that the anti-Stokes mark is missing, i.e. the document is fake.

Scale pos. 13 illustrates the radiation intensity of the anti-Stokes tag, thereby simplifying the use of the system, making its operation clear and clear.

Pos. 14 is used for the abbreviation of the selected test object;

Image pos. 15 shows the user the location of the anti-Stokes mark on the document or banknote being examined, simplifying and speeding up the authentication process (see FIG. 3).

The proposed system for determining the authenticity of banknotes and documents works as follows.

In smartphone pos. 3 with the Android operating system, a specially designed application for the operation of the portable set-top box pos.2 is installed.

Next, you need to connect a portable set-top box pos. 2 to the smartphone 3 for which a regular USB connector is used. Thus, the smartphone pos. 3 and portable set-top box pos. 2 form a single structural system.

Immediately after connecting the portable set-top box item 2, the application on the smartphone item 3 is loaded automatically and the system for determining the authenticity of objects is ready for use.

Then the user in the smartphone application pos. 3 using the drop-down list of types of studied objects pos. 9, as well as using the expanding list of objects pos. 10 selects the object to be checked, for example, Russian ruble (RUB) of 10 rubles. Thus, the user, having selected the necessary object for verification, sees pos. On the smartphone display. 3 tooltip in the form of image pos. 15, showing the user the location of the anti-stamp mark on the bill, and the application downloaded to the smartphone pos. 3 sends information about the radiation intensity of the anti-Stokes label to the portable set-top box pos. 2, since various types of documents, as well as banknotes of countries of different denominations, have different characteristics of an anti-Stokes label, in particular, radiation intensity, the application should be adapted accordingly.

To determine the authenticity, a portable set-top box pos. 2 to that part of the banknote indicated by the smartphone application pos. 3. Infrared LED pos. 6 low power irradiates the anti-Stokes label, and the photodetector of the photodetector pos. 7 together with the primary signal processing unit implemented in the microcontroller pos. 5, receives a response from the anti-Stokes tag. The secondary signal processing unit, also implemented in the microcontroller pos. 5, extracts information about the presence of the anti-Stokes tag and its characteristics, in particular intensity, against the background of interference and noise.

Received and processed information is sent via USB-connection to the smartphone pos. 3. The application in the smartphone pos. 3 displays the received data in the form of a numerical value, a variable-length scale, and an icon meaning “yes, the mark is detected” or “no, the mark is not” (see items 12 and 13 in FIG. 3).

At the same time, at the stages of receiving and processing information and electrical signals by the microcontroller pos. 5 the following is carried out.

Microcontroller pos. 5 is configured to independently turn on the infrared LED pos. 6 at some short intervals. And immediately, as soon as the microcontroller pos. 5 turns off the infrared LED pos. 6, the measurement of the value received by the photodetector pos. 7 signals.

Thus, having saved several tens of values in memory as an array, their analysis is ensured by calculating the integral, i.e. at the end of the pulse microcontroller pos. 5 digitizes data from the photodetector pos. 7 (see Figs. 3 and 4). If there are no phosphors, the signal will be like line B, if there is a phosphor, then the signal will be like line B, accordingly, by calculating the integral of the function, the radiation intensity of the anti-Stokes label will be obtained.

Thus, the fact of the presence of an anti-Stokes tag and the intensity of its radiation is established, and the amount of energy stored by the anti-Stokes phosphor and given to it later is determined, and the higher the concentration of the phosphor, the greater the energy reserve. It is important to note that other substances, such as paints, are not able to accumulate energy, so the presence or absence of an anti-Stokes label is clearly defined.

A significant feature of the proposed system is that the photodetector pos. 7 is configured to continuously receive optical signals in the infrared range and to analyze the array of received optical signals after turning off the infrared LED pos. 6 during the final afterglow of the phosphor, the duration of which is from one hundred to ten thousand microseconds. The indicated period of the completion of the afterglow of the phosphor is due to the physical properties of the phosphor contained in the protective label, and is explained by the fact that infrared radiation puts the phosphor molecules in an excited state, and when the radiation ceases to act, the atoms return to their normal state, spending energy on light radiation in the infrared range, taking time from 100 to 10,000 μs.

Thus, the sensitivity of the system increases, which reduced the power of the infrared LED pos. 6.

An essential technical technique is that the frequency of scanning infrared optical signals, receiving a response from them, and sending to the microcontroller the processing and control of incoming electrical and information signals pos. 5 is set to a multiple of 10 Hz, in this mode the system performs at least 16 measurements (where each measurement is the pulse of the infrared LED pos. 6 and digitization of the completed afterglow of the phosphor), then these values are averaged. Mostly the noise is concentrated in a certain spectrum (for countries with a frequency of 50 Hz, the noise is concentrated at a frequency of 100 Hz), so if you digitize a useful signal at frequencies that are not multiple of 10 Hz, the useful signal is summed in-phase, and the noise is random. Thus, the useful signal stands out against the background of noise interference, since the completing afterglow of the phosphor was the same in at least 16 cases, and the noise interference occurred with different phases - therefore, it weakened.

The proposed system for determining the authenticity of banknotes and documents is a small-sized device, convenient for carrying and easy to use, with high technical and operational characteristics.

All other smartphone features pos. 3 are saved.

The invention allows to use the processing power of a modern smartphone or tablet to process the received information signals, with the display of information on the display with the output of reference data.

The invention does not require the development and design of sophisticated technological equipment for mass production, but is suitable for the manufacture of general-purpose electronic products production lines.

The invention will find wide application in the field of determining the authenticity of banknotes, as well as other documents, the authenticity of which must be confirmed by the anti-Stokes tag.

Claims (1)

A system for determining the authenticity of banknotes and documents, including a portable set-top box equipped with a microcontroller, made interconnected with a computer, characterized in that the computer is made in the form of a portable electronic device containing a display and a microprocessor, configured to estimate the radiation intensity of anti-Stokes banknote labels of various denominations, and also various examined documents and sending the corresponding electrical information signal containing information about the intensity of exercises of anti-Stokes labels in the mentioned microcontroller, equipped with an infrared LED and a photodetector connected to it, configured to receive optical signals in the infrared range and analyze the received optical signals after turning off the indicated infrared LED during the luminescent phosphor afterglow, the duration of which is from one hundred to ten thousand microseconds while the frequency of emission of the optical signals of the infrared LED, receiving a response from them and sending installed in the microcontroller is not a multiple of 10 Hz, providing a desired signal isolation on a background noise interference with its subsequent digitization and disclosure.

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