RU2397546C1 - Method for visualisation of hidden information on security papers and items and spectral magnifying glass for its realisation (versions) - Google Patents

Abstract

FIELD: information technologies.

SUBSTANCE: method provides for item positioning regarding beam of radiation, irradiation of hidden information with pulse radiation that diverges at an angle in near infrared area of spectrum, and for observation by hidden information signs that luminesce in visible range of wave lengths. At the same time radiation is carried out by means of radiation pulses with duration of 0.04-0.06 seconds with frequency of 3-6 Hertz, and output capacity of radiation is identified on the basis of the following ratio:

where P^c(t) - capacity of radiation in near infrared area of spectrum measured at the distance of 100 mm from its source.

EFFECT: provides for visualisation with application of radiation sources, which are safe for eyes.

7 cl, 4 dwg

Description

The invention relates to optical-electronic instrumentation and can be used to verify the authenticity of securities, bank cards, banknotes and other products protected from counterfeiting by using hidden signs on them based on paints with anti-Stokes phosphors.

There is a method of visualizing hidden information on securities and products, which consists in irradiating the product with a radiation beam of an LED or laser with an output radiation power of 0.25-1.0 W and a wavelength of 0.96-0.99 microns and observing by luminescent in the visible range wavelengths signs of hidden information [1, 2].

The disadvantage of this method is the use of a LED or a high-power laser that is not visible to the eye by continuous radiation, which, according to sanitary rules and standards [3], relates to the second and third class of laser danger, which leads to damage to the retina when radiation enters the eye.

The closest technical solutions to the claimed are a method of visualizing hidden information on securities and products and a spectral magnifier for its implementation [4, 5]. The method consists in isolating the hidden information of the product from extraneous radiation, illuminating it with visible radiation, enlarging the image of the irradiated surface, positioning the product relative to the radiation beam, irradiating the radiation beam of an LED or laser with a continuous output power of 0.03 W and a wavelength of 0.96-0 , 98 microns and observations on the signs of hidden information luminescent in the visible wavelength range. Spectral magnifier [4] for implementing the method comprises an opaque case, an eyepiece mounted in the upper part of the case, an eyepiece slide fixed in the lower part of the case, at least two sources of white and infrared radiation, respectively, at least two switching buttons, the output of which electrically connected to the inputs of white and infrared radiation sources, respectively. The infrared radiation source includes a laser diode and is made with a radiation field angle of 6 °. Spectral magnifier [5] differs from magnifier [4] by using a video camera instead of an eyepiece with a cut-off infrared filter and a connector for connecting an external monitor or computer. The advantage of technical solutions [4, 5] is the introduction of operations to isolate the hidden information of the product from extraneous radiation, illuminate it with visible light, increase and position the image of the irradiated surface of the tested product, which allows you to quickly find the hidden information of the product and reduce the output power of the infrared radiation source by an order of magnitude compared with technical solutions [1, 2].

The disadvantage of technical solutions [4, 5] is the use of a LED or laser with a relatively high power of continuous radiation, not visible to the eye, with an angular field of 6 °, which, according to sanitary rules and standards [3], belongs to the second class of laser danger, which leads to retinal damage if it gets radiation in the eye.

The inventions are based on the task of creating a compact spectral magnifier that provides visualization of hidden information with eye-safe radiation sources.

The inventive method for visualizing hidden information on securities and products, which consists in isolating the product from extraneous radiation, illuminating it with visible radiation, enlarging the image of the irradiated surface, positioning the product relative to the radiation beam, irradiating radiation diverging at an angle φ in the near infrared region of the spectrum and observing the signs of hidden information that are luminescent in the visible wavelength range is that, in contrast to the prototype, irradiation is carried out by imp with radiation monitors lasting 0.04-0.06 seconds with a frequency of 3-6 hertz, and the output radiation power P ^c (t) is determined from the relation

where P ^c (t) is the radiation power in the near infrared region of the spectrum, measured at a distance of 100 mm from its source.

The essence of the invention in the spectral magnifier according to the first embodiment, comprising a lightproof casing, an eyepiece mounted in the upper part of the casing, an eyepiece slide fixed in the lower part of the casing, at least two sources of white and near infrared radiation, respectively, and at least two switching buttons, the outputs of which are electrically connected to the inputs of the sources of white and near infrared radiation, respectively, lies in the fact that, in contrast to the prototype, a pulse generator of length 0.04-0.06 seconds with a frequency of 3-6 hertz, the output of which is connected to a source of near infrared radiation, and the input is connected to a switching button to turn on a source of near infrared radiation, which is made with an angle φ of the radiation field and output power P ^c (t ) satisfying the relation

where P ^c (t) - power source of near infrared radiation, measured at a distance of 100 mm from the glass slide.

In the magnifying glass, the infrared radiation source is made in the form of an LED with an angular radiation field of at least 20 ° in the spectral range of 0.94-0.99 microns and is located near the microscope slide in the peripheral part of its field of view at an angle of 25-40 ° to the surface of the glass slide .

In the magnifying glass, sources of white and infrared radiation, switching buttons and a pulse generator are made as a single unit in the form of a printed circuit board on which these elements are soldered and fixed.

In the spectral magnifier according to the second variant, in contrast to the first variant, instead of an eyepiece, a video camera with a cut-off infrared filter and a connector for connecting an external monitor or computer is used.

A monitor is located in the magnifying glass of the second embodiment, located outside the upper part of the housing, the input of which is electrically connected through the connector to the video camera.

The irradiation of the tested product with radiation pulses with a duration of 0.04-0.06 seconds with a frequency of 3-6 hertz allows you to observe periodically flashing (flickering) luminescent signs on a dark background or their images, which makes it possible to visualize less bright latent images compared to constantly glowing luminescent image. In this case, the pulse duration of 0.04-0.06 seconds increases the maximum permissible radiation power P ^c (t) (see the appendix to the application), and the frequency of 3-6 hertz does not allow the flickering image to merge into a single image. Determination of the maximum permissible output power P ^c (t) depending on the angle φ of the divergence of radiation from the above ratio provides the possibility of obtaining a large number of sources of radiation safe for the eyes (calculations in the appendix to the application). Thus, the distinctive features of the proposed method solve the problem.

Introduction to the spectral magnifier of a pulse generator with a duration of 0.04-0.06 seconds and a frequency of 3-6 hertz, the output of which is connected to a source of near infrared radiation, and the input is connected to a switching button for switching on a source of near infrared radiation, which is made with an angle φ of the radiation field and output power P ^with (t), satisfying the above ratio, provides the possibility of implementing the claimed method of visualization of hidden information.

The implementation of the infrared radiation source in the form of an LED with an angular field of radiation of at least 20 ° and placing it near the slide of the eyepiece in the peripheral part of its field of view at an angle of 25-40 ° to the surface of the slide, in addition to solving the problem, allows you to simplify the magnifying glass by the use of a cheap LED without additional optics forming the angular field of radiation and through the use of LED circuits to position the protective element relative to the radiation beam. The placement of the LED in the peripheral part of the field of view of the eyepiece allows you to use the rest of the field of view of the eyepiece to identify other printing products protection products. The implementation of the source of infrared radiation in the spectral range of 0.94-0.99 microns, in addition to solving the problem, allows you to expand the functionality of the magnifier by visualizing IR luminescent protective elements luminescent at a shorter wavelength.

Performing in a magnifying glass sources of white and infrared radiation, a pulse generator and the first and second switching buttons as a single unit in the form of a printed circuit board on which these elements are soldered and fixed, in addition to solving the problem, reduces the dimensions of the device.

The use of a spectral video camera with a cut-off infrared filter and a connector instead of an eyepiece in the second version of the magnifier, in addition to solving the task, provides the convenience of visualizing hidden information and the possibility of recording and storing it.

Introduction to the spectral magnifier according to the second version of the monitor, located outside the upper part of the housing, the input of which is electrically connected through the connector to the video camera, in addition to solving the problem, provides the mobility of the magnifier with the comfort of visualizing hidden information.

The invention is illustrated by the functional diagrams of the spectral magnifier shown in Fig.1-4. Figures 1 and 2 show examples of the performance of a spectral magnifier according to the first embodiment, and Figures 3 and 4 - according to the second embodiment.

The spectral magnifier contains a lightproof casing 1, an eyepiece 2 (Fig. 1) or a video camera 3 with a detachable infrared light filter 4 and a connector 5 (Fig. 3), fixed in the upper part of the casing 1, and a glass slide 6 fixed in the lower part of the casing 1. The magnifier contains at least two sources 7 and 8, respectively, of white and near infrared radiation. The latter is made with the angle φ of the radiation field and the output power P ^with (t) satisfying the relation

where P ^c (t) is the power of the source of near infrared radiation, measured at a distance of 100 mm from a glass slide 6.

In the examples of FIGS. 1-4, the source of near infrared radiation 8 is made in the form of an LED with radiation in the spectral range of 0.94-0.99 microns with an angular radiation field of at least 20 ° and is located near the glass slide 6 in the peripheral part of the field of view or an eyepiece 2 (Fig. 1) or a video camera 3 (Fig. 3) at an angle of 25-40 ° to the surface of the slide 6. Inside the housing 1 are located a power source 9 and at least two switching buttons 10 and 11, the outputs of which are electrically connected with the inputs of the source 7 of white radiation and the source 8 and infrared radiation, respectively, and the inputs with a power source 9. The magnifier contains a generator of 12 pulses with a duration of 0.04-0.06 seconds with a frequency of 3-6 hertz, the output of which is electrically connected to a source of 8 near infrared radiation, and the input with a switching button 11. Outside the upper part of the housing 1, in the embodiment of FIG. 3, a monitor 13 is located, the input of which through the connector 5 is electrically connected to the video camera 3. The magnifier may contain additional radiation sources, for example, an ultraviolet radiation source 14 made in in the form of an LED with the corresponding switching button 15, and in the embodiment of FIGS. 3 and 4, an additional power switch 16 for the video camera 3 and monitor 13. The housing 1 contains four holes in which caps 17 are mounted kinematically connected with the switching buttons 7, 8 , 15 and switch 16. Sources 7, 8 and 14 of white, infrared and ultraviolet radiation, switching buttons 10, 11, 15, switch 16 and pulse generator 12 are made as a single unit in the form of a printed circuit board 18 on which these elements are soldered and fixed. To replace the power source 9, a sliding cover 19 is provided in the housing 1. The power source 9 is made in the form of either a rechargeable battery or one or two galvanic cells.

Visualization of hidden information on a spectral magnifier is as follows.

In the visualization mode of anti-Stokes security elements, a spectral magnifying glass 6 of a magnifying glass is mounted on the corresponding section of the item under test, for example, a Russian banknote. When using the spectral magnifier according to the first embodiment (Figs. 1 and 2), the pupil of the eye is combined with the exit pupil of the eyepiece 2, thereby isolating the hidden information on the bill from extraneous radiation that could pass through the eyepiece 2, which in the second embodiment is a spectral magnifier (Fig. 3) is provided constructively. Press the switching button 10 through the cap 17, which includes a white radiation source 7, which illuminates the bill with visible radiation, and, watching the enlarged eyepiece 2 (figure 1) or video camera 3 and monitor 13 (figure 3) image of the illuminated surface and the contour of the source 8, tentatively combine the contours of the source 8 with the section of the bill where the hidden information should be, thereby positioning the bill relative to the infrared beam. Then, the switching button 11 is pressed, thereby including the source of near infrared radiation 8, and the hidden information of the bill is irradiated with pulses of duration 0.04-0.06 seconds with a frequency of 3-6 hertz of radiation diverging at an angle φ, the output power P ^c (t) of which depending on the angle φ is determined by the above ratio. The incident invisible pulsed infrared radiation of the source 8 excites an anti-Stokes compound of the hidden information, and the operator observes periodically luminous signs of the hidden information in the visible wavelength range through the eyepiece 2 (Fig. 1) or their flickering images on the monitor 13 (Fig. 3).

In the control mode of micro-fonts, fluorescent seals or tags, erasers, a glass slide 6 is installed on the corresponding section of the identified product, for example a security. The corresponding switching button is pressed through the cap 17, and an enlarged image of a portion of the security is observed in the eyepiece 2 or on the monitor 13. If the switching button 15 is pressed, including the source of ultraviolet radiation 14, then a fluorescence image of seals or labels are observed that, without the presence of ultraviolet radiation, have a different color or are not visible. If the switching button 10 is pressed, including the source 7, then an enlarged image of a micro font or other printing security elements is observed.

Information sources

1. Patent RU 2137612, 1999

2. Patent RU 2174173, 2001

3. Sanitary norms and rules for the design and operation of lasers No. 5804-91. (San P and N No. 5804-91).

4. Spectral magnifier mod. 1013. Prospect of NPP Regula, 2002

5. The magnifier is video spectral mod. 4047. Prospect of NPP Regula, 2002

Claims (7)

1. A method of visualizing hidden information on securities and products, which consists in isolating the hidden information of the product from extraneous radiation, illuminating it with visible radiation, enlarging the image of the irradiated surface, positioning the product relative to the radiation beam, irradiating radiation diverging at an angle φ in the near infrared region of the spectrum and observation of signs of hidden information luminescent in the visible wavelength range, characterized in that
irradiation is carried out by radiation pulses with a duration of 0.04-0.06 s with a frequency of 3-6 Hz, and the output radiation power P ^c (t) is determined from the relation

where P ^c (t) is the radiation power in the near infrared region of the spectrum, measured at a distance of 100 mm from its source. 2. Spectral magnifier, comprising a lightproof casing, an eyepiece mounted in the upper part of the casing, an eyepiece slide mounted in the lower part of the casing, at least two sources of white and near infrared radiation, respectively, and at least two switching buttons, the outputs of which are electrically connected with inputs of sources of white and near infrared radiation, respectively, characterized in that a pulse generator of duration 0.04-0.06 with a frequency of 3-6 Hz, the output of which is electrically connected is connected with the source of near infrared radiation, and the input is with a switching button to turn on the source of near infrared radiation, which is made with an angle φ of the radiation field and output power P ^c (t) satisfying the relation

where P ^c (t) is the power of the near infrared radiation source, measured at a distance of 100 mm from the eyepiece slide. 3. The magnifier according to claim 2, characterized in that the infrared radiation source is made in the form of an LED with an angular radiation field of at least 20 ° in the spectral range of 0.94-0.99 microns and is located near the object glass of the eyepiece in the peripheral part of its field of view at an angle of 25-40 ° to the surface of the slide. 4. The magnifier according to claim 2 or 3, characterized in that the sources of white and infrared radiation, a pulse generator and switching buttons are made as a single unit in the form of a printed circuit board on which these elements are soldered and fixed. 5. Spectral magnifier, comprising a lightproof housing, a video camera with a cut-off infrared filter and a connector, mounted in the upper part of the housing, a slide mounted in the lower part of the housing, at least two sources of white and near infrared radiation, respectively, and at least two switching buttons, the outputs of which are electrically connected to the inputs of the sources of white and near infrared radiation, respectively, characterized in that a pulse generator with a duration of 0.04-0.06 is introduced into it frequency of 3-6 Hz, the output of which is electrically connected to a source of near infrared radiation and input - with the switching power button near infrared source which is designed with an angle φ of the radiation field and an output power P ^c (t) satisfying the relation

where P ^c (t) is the power of the source of near infrared radiation measured at a distance of 100 mm from the slide. 6. The magnifier according to claim 5, characterized in that the infrared radiation source is made in the form of an LED with radiation in the spectral range of 0.94-0.99 microns and is located near the slide in the peripheral part of the field of view of the camera at an angle of 25-40 ° to glass slide surface. 7. The magnifier according to claim 5 or 6, characterized in that a monitor is placed in it, located outside the upper part of the housing, the input of which is electrically connected through the connector to the video camera.

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