RU2355033C1 - Method of determining banknote authenticity during high-speed sorting and device for determining banknote authenticity during high-speed sorting - Google Patents

Abstract

FIELD: physics; marking.

SUBSTANCE: present invention relates to methods and devices for determining banknote authenticity during high-speed sorting. The method involves successive exposure of a security mark with two radiation sources with different wavelengths, recording the intensity variation profile, waiting for deviation of the excited region of the security mark from the field of vision of photodetector, and repetition of the cycle, giving rise to spatial separation of excited regions that way. The device has emitters for exciting luminescence in the security mark, a photodetector for receiving radiation emitted by the excited security mark and an analysing device for recording information received by the photodetector and comparing it with given information.

EFFECT: more accurate determination of banknote authenticity during high-speed sorting.

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Description

The invention relates to methods and devices for determining the authenticity of banknotes in the implementation of high-speed sorting.

Known DE patent No. 10127837, which describes a method for determining the authenticity of banknotes during high-speed sorting, including exposing the security label at a given constant wavelength and receiving a luminescence signal from it, followed by fixing the profile of the change in luminescence intensity and comparing it with a given profile. Also described is a device for determining the authenticity of security features on valuable documents, containing two emitters, a photodetector and means for fixing the profile of the change in luminescence intensity and comparing it with a given profile.

A limitation of the known technical solution is the inability to identify new, more secure tags.

The technical result of the invention is to increase the reliability of determining the authenticity of banknotes in high-speed sorting of banknotes.

The specified technical result is achieved by the fact that in the method for determining the authenticity of banknotes during high-speed sorting, including exposing the security mark and receiving a luminescence signal from it, followed by fixing the profile of the change in the luminescence intensity and comparing it with a given profile, in contrast to the known one, they are sequentially exposed by two emitters with at different wavelengths, a portion of the protective mark with an area of the exposed portion exceeding the field of view of the photodetector, an increase in the signal is recorded the luminescence excited by the emitter with the first wavelength, which is then turned off, and turn on the emitter with the second wavelength when the protective mark has luminescence excited by the emitter with the first wavelength, then the decay of the luminescence signal at the moment when the excited region leaves the field view of the photodetector, while fixing the profile of the change in the luminescence intensity after the entire cycle of operations.

In addition, the technical result is achieved in that the device for determining the authenticity of banknotes during their high-speed sorting contains several pairs of emitters with different specified wavelengths to irradiate the entire surface of the banknote, a photodetector and means for fixing the profile of the change in luminescence intensity and comparing it with a given profile, according to the invention implements the claimed method, while the emitters are made with the possibility of irradiating the protective label with different wavelengths, and the analyzing device consists of a system of signal amplifiers, a multiplexer, an analog-to-digital converter, a programmable logic integrated circuit and a processor for processing the luminescence signals of the label excited by emitters with different wavelengths.

The invention is illustrated by the following drawings:

figure 1 - movement of a banknote with a protective mark in the field of view of the photodetector;

figure 2 - diagram of a device for determining the authenticity of banknotes;

figure 3 is a luminescence intensity profile over time;

figure 4 is a sequence diagram of the operation of radiation sources with a wavelength of λ ₁ and radiation sources with a wavelength of λ ₂ .

A device for determining the authenticity of banknotes consists of radiation sources 1 with a wavelength of λ ₁ and radiation sources 2 with a wavelength of λ ₂ . They are arranged in two rows on both sides of the InGaAs-based luminescence detector 3, each of them is located at an angle of 45 ° to the security mark 4 applied to the banknote 5 that is moving along the field of view of the photodetector 6. Position 7 indicates the control path, and the arrow indicates the direction of movement of the banknote (figure 1).

Between each radiation source 1 and 2 and the protective label 4 are light filters 8 made of colored glass (figure 2). The photodetector 6 consists of a sequentially arranged lens filter 9, an interference filter 10 and a luminescence detector 3.

The outputs of the luminescence detector 3 through the amplifiers 11 are connected in series with the multiplexer 12, the analog-to-digital converter 13 and the controller 14. The controller 14 consists of a programmable logic integrated circuit 15 (FPGA) and the processor 16. One output from the controller 14 is connected to the interface board 17, on which installed power supplies, an interface controller that interacts with the controller of a counting and sorting machine (not shown in FIG.). The second output from the controller 14 is connected to the lighting module 18, which in turn is connected to radiation sources 1 and 2.

The device operates as follows: when the controlled banknote 5 moves, when the security mark 4 falls into the field of view of the photodetector 6, the lighting module 18 includes radiation sources 1 with a wavelength of λ ₁ (t ₁ in Fig. 3). The filter 8 eliminates spurious emissions from the radiation source 1. When the protective mark 4 is exposed, luminescence is excited, which enters the photodetector 6, in which it is converted into a parallel beam of rays when the filter lens 9 passes. The interference filter 10 filters out the signal from the protective mark from the total luminescence flux 4 and transmits it to the luminescence detector 3. The output signal of the luminescence detector is amplified in the system of amplifiers 11.

In the multiplexer 12, the signals received from the amplifiers are combined into one signal, which then passes into the analog-to-digital converter 13, in which this signal is converted to a digital code. This digital code enters the controller 14, in which, in the programmable logic integrated circuit 15, the data are processed first, the serial code is converted to parallel, the regression parameters are calculated, and the calculated parameters are transmitted to the processor 16, which registers the growing luminescence excited by the radiation sources 1. After a while t _{1, the} processor 16 supplies a signal to the lighting module 18, which turns off the radiation sources 1 and simultaneously turns on the radiation sources 2 with a wavelength of λ ₂ (t ₂ in FIG. 3).

Then, a falling inertial luminescence signal excited by radiation sources 1 with a wavelength of λ ₁ is received and an increasing luminescence signal excited by radiation sources 2 with a wavelength of λ ₂ . This signal arrives at luminescence detector 3, travels all the way, and increasing luminescence excited by radiation sources 2 with a wavelength of λ ₂ and a decay of the inertial luminescence signal excited by radiation sources 1 with a wavelength of λ ₁ are recorded. After a time t _{2, the} lighting module 18 turns off the radiation sources 2 with a wavelength of λ ₂ . At time t ₃ (t ₃ in Fig. 3), the luminescence detector 3 receives a decaying inertial luminescence signal excited by radiation sources 1 and 2. This signal also goes all the way, the decay of the luminescence signal at time t ₄ is recorded, and the intensity change profile is recorded luminescence in time, compared with a given profile, and a decision is made on the authenticity of the banknote.

The time period with t ₄ no t _{5 is} not informative, during which time the excited region of the mark leaves the field of view of the photodetector 6.

Figure 3 shows the profile of the change in luminescence intensity over time.

Curve 19 - the intensity of the luminescence excited by the emitter with a wavelength of λ ₂ .

Curve 20 - the intensity of the luminescence excited by the emitter with a wavelength of λ ₁ .

Figure 4 shows the sequence diagram of the operation of radiation sources with a wavelength of λ ₁ and radiation sources 2 with a wavelength of λ ₂ .

The proposed method and device for determining the authenticity of banknotes can be used in enterprises using high-speed sorting of banknotes. The proposed technical solution allows to ensure the reliability of determining the authenticity of banknotes at high speeds of equipment for sorting banknotes.

Claims (3)

1. A method for determining the authenticity of banknotes during high-speed sorting, which consists in exposing a protective mark and receiving a luminescence signal from it with subsequent registration of a profile for changing the luminescence intensity, in this case, a section of a security mark with an exposed area exceeding the field of view is exposed sequentially by two emitters with different wavelengths photodetector, an increase in the luminescence signal excited by the emitter with the first wavelength, which is then turned off, and including They start emitting a second wavelength emitter when the protective mark has luminescence received from the first wavelength emitter, turn off the second wavelength emitter and register the intensity change profile due to natural decay, after which the excited region of the protective mark is expected to leave the field of view of the photodetector registering the profile of the change in luminescence intensity over time, compare it with a given profile and decide on the authenticity of the banknote. 2. A device for determining the authenticity of banknotes during their high-speed sorting, containing emitters for exciting the luminescence of the protective mark, made in the form of irradiation sources of different specified wavelengths, a lighting module designed to turn on and off these radiation sources, a photodetector for receiving the emitted excited protective mark of radiation , the output signal from which is intended for amplification in the system of amplifiers with their subsequent combination in a multiplexer, the signal from which It is intended for entering into an analog-to-digital converter, and subsequent processing in the controller, a processor for recording the processed data of the obtained luminescence excited by the radiation sources, and supplying a signal to the lighting module to turn off one radiation source and turn on another radiation source, as well as register the intensity change profile luminescence in time, for subsequent comparison with a given profile and deciding on the authenticity of a banknote. 3. The device according to claim 2, characterized in that several pairs of emitters with different specified wavelengths are installed to irradiate the entire surface of the banknote.

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