RU77460U1 - DOCUMENT AUTHORITY CHECK DEVICE - Google Patents

Abstract

The utility model relates to the field of authentication of securities and documents previously protected in a certain way. The technical result consists in increasing the signal to noise ratio. The technical result is achieved in that in a device containing a control and processing device; an image receiver of a test document connected to a control and processing device; an optical image pickup system optically coupled to an image receiver of the document to be examined, a quantum document image amplifier is further introduced to illuminate the document to be examined and to enhance the brightness of the radiation reflected from the document being examined; a power source of a quantum document image amplifier connected to said control and processing device, the control and processing device being used to control the operation of the quantum document image amplifier and the image receiver of the document to be examined and to process the received image document of the image document to be examined.

Description

The invention relates to the field of authentication of securities, documents, and other products that are preliminarily protected in a certain way and which moderately absorb the radiation of the visible or near infrared region of the spectrum.

In recent years, the rapid development of computer technology has contributed to the creation of modern automated spectroscopic complexes. Such complexes allow the automatic study of the optical and luminescent properties of objects in a wide spectral range. In particular, this refers to the possibility of identifying existing optical means of protecting securities and documents, which are largely based on optical spectroscopic methods. Existing protection methods use classic dyes and phosphors, which, once identified, can be used to make counterfeit copies of protected objects.

The creation of quantum electronics has opened up the possibility of developing laser-based amplifiers for the brightness of light. It turned out that pulsed metal vapor lasers (copper, gold, barium, lead, and a number of others) possess suitable characteristics.

In a laser projection microscope, a tube with a brightness amplifier simultaneously weakly illuminates the object and, amplifying the light reflected from it (carrying all information about it), provides bright screen illumination. In this case, the brightness increases to 10 thousand times. The whole system works only for short pulses, the duration of which is several tens of nanoseconds. The pulse repetition rate can reach several kilohertz, which means that a few can be examined per second

tens of thousands of objects. In some complex cases, several pulses of starting a quantum brightness amplifier can be spent on one object.

With the help of a copper vapor amplifier, vivid images of micro-objects were obtained with an increase of up to 15 thousand times on a screen with an area of up to 25 square meters. All this lies far beyond the capabilities of conventional optical systems. Optical systems with brightness amplifiers are a new area of modern optics.

The absence of brightness amplifiers hindered the solution of one common and very topical problem - miniaturization of recording large volumes of information. Currently, there is the possibility of such a recording - holography, for example, allows you to record one page of printed text on an area of approximately one square millimeter. But this problem has another side - extracting information from these super-miniature volumes. After all, just like an object under a microscope, a storage medium (for example, a film) may not withstand the strong illumination necessary for a large increase. The use of light amplifiers would eliminate many of these difficulties.

Since quantum amplifiers are the only existing amplifiers for the brightness of objects, and the gain reaches 10 ⁴ , when using them, individual nanoparticles can be detected, which is impossible by other methods.

For this reason, it is possible to achieve:

1. The use of a small number of markers;

2. Perhaps the formation of a small number of image markers, which cannot be detected by other methods.

In the prior art, a document authenticity control device is known (Utility Model Certificate RU 11619, 03/01/1999), which is selected as a prototype and which implements an optical method for recognizing tags visible only in infrared light. To simplify

the identification process in this device, an electron-optical converter is introduced into the optical circuit, which converts invisible infrared radiation containing information about the protected document into the visible range, which allows visualization of hidden marks.

Such a device does not increase the brightness of the image, but simply transfers it to a different spectral range. The noise characteristics of the signal can only deteriorate.

The technical result of the present invention is to increase the signal to noise ratio.

The technical result is achieved by the fact that in the device for authenticating documents containing a control and processing device; an image receiver of a test document connected to a control and processing device; an optical image pickup system optically coupled to an image receiver of the document to be examined, a quantum document image amplifier is further introduced to illuminate the document to be examined and to enhance the brightness of the radiation reflected from the document being examined; a power source of a quantum document image amplifier connected to said control and processing device, the control and processing device being used to control the operation of the quantum document image amplifier and the image receiver of the document to be examined and to process the received image document of the image document to be examined.

Figure 1 shows a diagram of the claimed device, where 1 is the document being checked, 2 is the lens of the receiving system, 3 is a quantum image amplifier, 4 is the optical system of the image receiver, 5 is the image receiver, 6 is the control and signal processing system, 7 is power supplies of a quantum image amplifier.

The device operates as follows: on a command from the control and signal processing system (6), signals are simultaneously transmitted to the power source (7) and to the image receiver (5) to start the duty cycle.

After receiving an electric pump pulse from the power source (7), spontaneous emission from the excited levels of the quantum amplifier (3) through the lens (2) falls on the protected object under investigation (1). The radiation reflected from the protected object being examined (1) is returned through the lens (2), amplified in a quantum amplifier (3), and through the optical system (4) it reaches the image receiver (5). After processing the signal in the control and signal processing system (6), a decision is made on the authenticity of the inspected object.

The device uses the achievements of quantum electronics, allows you to work with securities, documents and other products using the minimum number of nanoparticles, in the limit of several units or tens of pieces.

A quantum amplifier increases the brightness of the image in a narrow spectral region by several thousand times, while in the rest of the spectrum, which determines the noise component for the signal under study, such amplification does not occur or occurs with much lower efficiency. This circumstance makes it possible to increase the signal-to-noise ratio and recognize useful signals that cannot be obtained by classical methods, since they are recessed in noise.

We propose to use a quantum image amplifier instead of an electron-optical converter, which can improve the noise characteristics of the signals under study, and therefore significantly facilitate the recognition of labels.

Claims (1)

A document authentication device comprising a control and processing device, an image receiver of a test document connected to a control and processing device, an optical image receiving system optically coupled to an image receiver of a document to be examined, characterized in that it comprises a quantum document image amplifier for illuminating the studied document and amplification of the brightness of the radiation reflected from the document under study, the power source of the quantum amplifier The document is connected to the aforementioned control and processing device, and the control and processing device is used to control the operation of the quantum document image amplifier and the image receiver of the document to be examined and to process the image received by the image receiver of the image document under study.