RU2139571C1 - Detection of counterfeit entities - Google Patents

Abstract

FIELD: detection of counterfeit money and the like. SUBSTANCE: for detecting counterfeit entities use is made of means for irradiating entity under test with ultraviolet rays, detector that functions to detect light reflected from mentioned entity at first wavelength in first frequency band and fluorescent light from mentioned entity at second wavelength in second frequency band differing from first frequency band; mentioned second frequency band includes wavelengths in which counterfeit entities may fluoresce when exposed to mentioned ultraviolet light and standard level of light from irradiating means; use is also made of means for taking decision if mentioned entity is counterfeit and for adequate display; the latter means responds to detected reflected light and detected fluorescent light; it incorporates device for comparing output measurement signal with signal of detected standard level of light. Detector is arranged so that standard level of light does not actually depend on if entity under test is present or not. EFFECT: improved accuracy of detection. 18 cl, 10 dwg

Description

 This invention relates to the detection of fake objects. In particular, it relates to the detection of fake objects by identifying unauthorized materials from which the object is made or onto which it is applied by printing or formed in any other way.

 The production of counterfeit objects, in particular counterfeit banknotes, continues to increase amid the ongoing improvement in printing technology, in particular color printing. Fake banknotes appeared, which are almost impossible to distinguish with the naked eye from the real ones.

 Original banknotes are currently mainly issued in accordance with a specific technology, in particular using secure or unbleached paper. Counterfeit notes, on the other hand, are usually not always made from bleached paper. There is a method of distinguishing bleached paper from unbleached by viewing the paper under a source of ultraviolet radiation, such as an ultraviolet lamp (UV), which emits light with a wavelength in the range from 300 to 400 nm.

 Bleached paper includes chemical compounds that fluoresce under ultraviolet radiation, that is, the molecules that make up the paper are excited and emit light with a longer wavelength lying in the range from 400 to 500 nm. Since wavelengths from 300 to 400 nm usually lie outside the spectral range of the human eye, and wavelengths from 400 to 500 nm lie within this spectral range, the fluorescence phenomenon allows some fakes to be detected using the human eye.

 This process can be automated by using electronic means, including a sensor and a comparator, which compares the intensity of the fluorescence measured by the sensor with a reference level to indicate that the paper is probably (or is not) fake. Such a device is disclosed in US-A-4 558 224. However, some genuine banknotes, when washed, acquire chemical compounds that fluoresce, and some counterfeit banknotes are made of paper that contains little or no fluorescent materials. Thus, the phenomenon of fluorescence does not always accurately indicate whether or not a banknote is false.

 US-A 4,296,326 discloses a device for checking documents, such as banknotes, in which a document is moved along drums past detectors. This device also measures the fluorescence of the document when the latter is irradiated with ultraviolet light. Then additional tests are carried out. The test includes determination of reflected ultraviolet radiation. This is to determine if the document contains a particular type of watermark. The check includes measuring the reflectivity in one zone of the banknote (outside the zone where a watermark is expected) and comparing the obtained value with the measurement data inside the watermark zone. Thus, the ultraviolet reflection test is limited only to determining changes in the reflectance of the banknote in the transverse direction and the measurement should be performed in specific known areas of the banknote.

The present invention provides an apparatus for detecting counterfeit banknotes, which comprises:
means for irradiating the test object with ultraviolet light,
detector means for detecting: (I) reflected light from a specified object having a first wavelength inside the first wavelength range, (II) fluorescent light from an object having a second wavelength inside a second wavelength different from the first wavelength range, wherein said second wavelength the range includes the range of waves at which fake objects can fluoresce when they are irradiated with the indicated ultraviolet light, and (III) a reference level of light from the irradiation means, the means of ektirovaniya provides an output measuring signal depending on the detected reflected light and the detected fluorescent light,
decision making means for establishing whether or not the indicated object is fake and providing an appropriate indication, the decision making means responding to the detected light and the detected fluorescent light and includes comparison means for comparing the output of the measuring signal with a certain reference light level,
according to the invention, the detection means is arranged in such a way that the reference light level is practically independent of the presence of the test object.

 The invention also provides a method for determining the authenticity of a test object by using a fake detection device.

 The specified method includes irradiating the test object with ultraviolet light and determining authenticity based on the detected fluorescence of the test object and the ultraviolet light reflected from it, according to the invention, the test first includes the operation of manual positioning, the detection device and the test object relative to each other and, for authenticity, measuring the reflected ultraviolet radiation whose magnitude is determined by absolute reflectance STI test object rather than on the relationship between the reflectivity in different areas of the object.

The invention is further illustrated by specific embodiments with reference to the accompanying drawings, in which:
FIG. 1 is a top view of a first embodiment of a device according to the invention;
FIG. 2 is a sectional view taken along line II-II of FIG. 1 according to the invention;
FIG. 3 shows a section through III - III in FIG. 1 according to the invention;
FIG. 4 depicts a block diagram of a processor according to the invention;
FIG. 5 is a block diagram of a second embodiment of a fake detection device according to the invention;
FIG. 6 depicts a General view of a portable scanning device containing the inventive device according to the invention;
FIG. 7 depicts a portable device (side view) according to the invention;
FIG. 8 shows a portable device (front view) according to the invention;
FIG. 9 shows another embodiment of a portable device according to the invention;
FIG. 10 shows a portable device (bottom view) according to the invention.

 It has been found that genuine and counterfeit banknotes often have different reflectivity, in particular if they are exposed to ultraviolet radiation in the range from 300 to 400 nm. Thus, using two tests to measure both fluorescent light and reflected light from a banknote subjected to ultraviolet irradiation, the banknote can be declared genuine or false with great confidence.

 In FIG. 1 shows a device for irradiating a banknote with light and then measuring the magnitude of the fluorescent and reflected light.

 The device comprises an almost rectangular container 100 having a window 102, opposite which a banknote to be checked is placed. Inside the container 100 there is an elongated light source 104 for generating a luminous flux with a wavelength within 365 nm, which exits through the window 102. Inside the container there are also two photodiodes 105 and 106, separated from each other, but installed at such angles that their optical the axes intersect on the outer surface of the window 102. Each photodiode 105 and 106 is mounted on the substrate of the tubular opaque casing 108 and 110, respectively. The inner walls of the casing are coated with reflected material to increase the sensitivity of the photodiodes. The casing 108 is closed by a 365 nm bandpass optical filter, and the casing 110 is closed by a 450 nm bandpass optical filter.

 The lamp 104 is surrounded on three sides by a reflective material 116, such as aluminum foil, which reflects light mainly in the direction of the window 102 to concentrate the light on the window.

 Preferably, the reflective material would also be located around the light source, so that the optical plane of the light directed at the window has the same angle with the window as the optical axes of the photodetectors, which ensures that the photodetectors receive the maximum fluorescent and maximum reflected light from any banknote located on window 102.

 There is a glass plate on the window 102, which reflects part of the light that travels from the source 104 back to the photodiode 105. The light is mainly reflected back from the glass-air interface of the plate, which is usually about 8% of the light flux directed to the glass plate.

 If a genuine banknote is placed on the window, the amount of reflected light at 365 nm is usually quite small. Most often, the amount of reflected light increases from 8% to a value in the range from 12 to 18%. Thus, it is clear that the light reflected from the plate, if there is no banknote, can be used as a reference level to compare the degree of reflection in the case where the banknote is present.

 Any attenuation of the luminous flux from the lamp due to aging or any other defect is automatically compensated. Other errors are also excluded because the light paths and components used to determine the reference level remain the same as the light paths and components used to take measurements.

 In the case of fluorescence, the amount of fluorescent light emitted by a fake banknote is usually several orders of magnitude higher than the amount of light emitted by a genuine banknote, and thus, any degradation of the light source 104 is either very small or does not affect the detection of fluorescent light.

 An electronic processor (not shown) will be described in more detail below, continuously monitoring the radiation perceived by two photocells when the lamp 104 is turned on. In the absence of a banknote on the window, the photocell 105 provides a constant output signal. As soon as a banknote is placed on the window, the output of the photocell 105 increases and then a trigger signal is generated to activate the two measurement circuits to measure the output signals of the two cells 105 and 106.

 Measuring circuits provide the reading of data that can be displayed using the display 126, and the decision circuit, reacting to the received data, activates one of the two optical indicators 122 and 124, respectively, indicating that the banknote is genuine or false.

 A printer (not shown) may be provided for printing the values displayed on the display 126.

 The device automatically activates when the banknote is placed on the window to determine if the banknote is genuine or false.

 In FIG. 4 shows in more detail a block diagram of a processor. Each photocell 105 and 106 acts on the respective trigger circuits 130 and 132, which detect a rapid change in signal, for example, as a result of placing banknotes on the window. Any one or both of the trigger circuits 130 and 132 provides a signal to the actuator 134, which drives the two measurement circuits 136 and 138 (for example, by supplying them with power or removing the ban on their operation). Delay circuit 140 suspends the operation of measurement circuits 136 and 138 after a short measurement period. The first comparator 142 compares the output of the photocell 105 with a reference value stored in the memory 144, and if the detected value exceeds the reference, an output signal is generated that is simultaneously supplied to the logic elements 146 and 148. The signal stored in the memory 144 is received from the photocell 105 when the device is at rest. The output of the photocell 105 is amplified by an amplifier 150 with a coefficient of 20% to 50% and recorded in the memory 144. As soon as the Executive unit 140 is switched, the amplifier 150 is closed, so that the memory 144 only stores a constant value of the reflected light. The comparator 152 compares the output signal of the measuring circuit 138 with the reference value 154 and, if the reference value is exceeded, generates an output signal that is supplied to the two logic elements 146 and 148.

 Logic element 146 is triggered when a genuine banknote is detected that excites indicator 122. In the same way, gate 148 is triggered by exciting indicator 124 if a fake banknote is detected. The current output values of the two measurement circuits 136 and 138 are provided to a display 126 for display.

 Obviously, the value of the reference signals stored in the memory devices 144 and 154 can be adjusted if necessary.

 Due to the possible effects of external illumination of the cells 105 and 106, the device is shielded by a lid, in which there is a gap through which the banknote can be placed on the window.

 Instead, the light source can be modulated at the selected frequency and the output signals of the photodiodes can be demodulated at the same frequency to eliminate the effect of external illumination.

 If a more accurate measurement of the fluorescent signal is required, it can be normalized to the reference level in the same way as the reflected signal.

The following relation is used for approximation:
t _S = (P _S / P _r ) • t _g / (1-r _g ) ²
where P _S is the reflected part of the radiation signal from the sample, P _r is the part returned from the glass plate for use as a reference, r _g is the reflection coefficient from the glass plate. It should be noted that the effect of changes in r _{g is} negligible if this coefficient is small, and significant if it can be large. This ratio is essentially nonlinear and simplified to a first approximation. If necessary, a more accurate expression may be given.

 Obviously, the ultraviolet reflection from the banknote depends on the degree of contamination. The degree of contamination can be measured and compensated by adjusting the corresponding stored reference values.

 The device shown in FIG. 5, measures both fluorescent light and reflected light, using a single unit to determine if a banknote is fake or genuine.

 The device comprises an ultraviolet lamp 2, which is preferably mounted on a portable scanning device. Lamp 2 emits at a known frequency at which fluorescence of bleached paper occurs.

 The detector 3 is designed to receive both fluorescent and reflected radiation from banknote 1, but not directly from lamp 2, bypassing the reflection phase. The control unit 3 may be a photodiode or phototransistor, sensitive, for example, to the corresponding frequency or frequencies of light. In particular, the control unit must be sensitive to fluorescent light in the range of 400 to 500 nm and to reflected ultraviolet light in the range of 300 to 400 nm so as to respond to counterfeit notes from bleached paper that fluoresce, or counterfeit notes that do not fluoresce, but since they are counterfeit, they often have a higher reflectance to ultraviolet light than genuine banknotes. An electrical signal is supplied from the control unit 3 to one of the inputs of the comparator 4.

 The second detector or control unit 5 is installed to receive ultraviolet radiation directly from the lamp 2. The signal from it is first amplified by an amplifier 6 and fed to a resistor 7, the other end of which is grounded. Thus, the voltage across the resistor 7 is proportional to the radiation intensity of the lamp. The resistor 7 is part of a potentiometer, the sliding contact of which is used as the second input of the comparator 4. The sliding contact can be set to provide a threshold value representing a predetermined voltage proportional to the intensity of ultraviolet radiation.

 The comparator 4 is designed to provide a signal if the signal received by the control unit 3 is greater than or equal to the set detection threshold. If the threshold is reached, this means that some of the light incident on banknote 1 was reflected or re-emitted in the form of fluorescence, and thus it can be assumed that the banknote is false.

 The signal from the comparator 4 is fed through a low-pass filter (for example, an RC filter 8, 9, as shown in Fig. 5) to the timer 10. This timer generates a pulse, for example, of the order of one second, which activates the buzzer 11 and a visual alarm in the form of an LED ( LED) 12. In this example, the buzzer 11 and the LED 12 are installed in parallel between the output bus of the timer 10 and the ground. As an additional or alternative option, other types of alarms can be used, sound or visual, or both. The output pulse of the timer 10 can also be applied to the output amplifier 13, which is designed to supply the appropriate signal for use in the control system. This control system can be used to send a warning signal to a remote control point, for example, the administration or the security service in the store that a fake banknote has been detected. Thus, as an alternative or in addition to warnings at the place of purchase, that is, at the checkout, the security service and the administration are informed separately. An output amplifier in one embodiment may provide TTL (transistor-transistor logic) signals.

 It is useful to be able to continuously monitor directly the output signal of the lamp so that you can notice a weakening of the glow of the lamp and thus replace it in time. In the example shown in FIG. 6, this is achieved by supplying the output signal of the amplifier 6 to the first input of the second comparator 14. The other input of the comparator 14 is connected to a potentiometer 15, which is used to set the lower threshold voltage value controlled by the control device of the lamp 5 and which is thus proportional to the intensity of the lamp 2. If the signal from the amplifier 6 is less than this lower threshold value, the signal at the output of the comparator 14 is supplied to a warning means, for example, a second LED 16, which is an indicator of the lower the lamp radiation. The glow of this LED warns the operator that it is necessary to replace the lamp or one of its parts.

 It is most preferable to make the device in the form of a portable scanning device; one of the housing options in which the device can be placed is shown in FIG. 6 - 8. The device has a head 17, in which an ultraviolet lamp 2 is mounted to irradiate an object placed directly under the head. The handle 18 is preferably shaped, for example, with several protrusions for convenient hand grip. Power is supplied to the device through a power cord 19, which can come from the network, from a neighboring ticket office or from an emergency power source, or in another way. For greater mobility, as an alternative, the device can be powered by batteries, which can be rechargeable. A main switch 20 is provided, which turns on the irradiation lamp 2, and thus activates the counterfeit detection device only when the switch is pressed with the thumb, for example, when the device is held in a hand. If this design is used, the device is installed for operation only in the scanning position. In one embodiment, the signal to a remote control and monitoring center, such as a security service, may be transmitted over a backbone network. This can be achieved by using pulses of known frequency in the backbone network. If different devices use different frequencies, then the operator on the remote control when receiving a signal about the appearance of a fake banknote will be able to find out which scanning device identified this banknote.

 The device can be temporarily mounted, for example, on a bracket in the working and / or non-working position. Portability and adaptability of the device allows you to use it in various situations, including with other devices.

 It should be noted that the detection circuit only works effectively when the ON / OFF switch is used to turn on the lamp, which minimizes energy consumption and reduces the likelihood of a false reaction to objects that do not need to be tested.

 An alternative embodiment of a portable scanning device in the form of a rod is shown in FIG. 9 and 10. The rod comprises a cylindrical body 58 with a switch 60 on one side and an ultraviolet lamp on the opposite side. A sensor 64 is located adjacent to the lamp 62. The device operates in the same way as the device shown in FIG. 6 - 8.

 Counterfeit objects can be not only banknotes, but also any object whose authenticity is to some extent determined by the type of paper or other material from which it is made or printed. In some embodiments, the genuine item may glow under the influence of ultraviolet light, and in this case, the device can be suitably modified, for example, by rearranging the input connections on the comparator 4 so that the alarm is triggered when the signal is less than the threshold value.

Claims (18)

 1. A device for detecting fake objects, comprising means for irradiating the test object with ultraviolet light, a detector for detecting reflected light from said object having a first wavelength inside the first wavelength range, fluorescence light from said object having a second wavelength inside the second wavelength range, different from the first wavelength range, wherein said second wavelength range includes wavelengths at which fake objects can fluoresce when exposed to the action of the indicated ultraviolet light and a reference level of light from the irradiating means, the detector being designed to provide a measuring output signal depending on the detected reflected light and the detected fluorescent light, and decision making means for determining whether the indicated object is fake and providing an appropriate indication, wherein the decision making means responds to the detected reflected light and the detected fluorescent light and turns on the means a method for comparing the measuring output signal with the signal of the detected reference light level, characterized in that the detector is positioned so that the reference light level is virtually independent of the presence of the test object.  2. The device according to claim 1, characterized in that the second wavelength range is within the range of 400 to 500 nm.  3. The device according to claim 1 or 2, characterized in that the detector is designed to detect individual signals, respectively indicating the level of reflected ultraviolet light and the level of fluorescent light.  4. The device according to claim 3, characterized in that it contains a comparison tool for comparing the signal of the reflected ultraviolet light with the signal of the detected reference light level.  5. The device according to claim 4, characterized in that the detector contains the first and second photocells designed to receive light from the object, moreover, through the first optical filter only for light in the first wavelength range and through the second optical filter only for light in the second wavelength range .  6. The device according to claim 5, characterized in that the detector is designed to generate a signal representing a reference light level in response to the output signal of the first photo cell in the absence of the test object.  7. The device according to claim 1, characterized in that it includes a glass plate for positioning the object on one side with the irradiation means and detectors located on the other side of the plate and facing the object through the glass plate.  8. The device according to claim 7, characterized in that it contains a standard for storing the first reference level, which is a function of the light reflected by the glass plate in the absence of an object on it and received by the photo cell.  9. The device according to claim 8, characterized in that in it the optical axis of the photocells and the irradiation means converge on the surface of the glass plate that is designed to install the object.  10. The device according to claim 1, characterized in that it contains means that are triggered when a signal is received from the detector to record the values of the received signals having a wavelength in the first and second ranges.  11. The device according to claim 1, characterized in that the decision-making means comprises means for the first indication when the object is fake, and for the second, different from the first when the object is genuine.  12. The device according to claim 1, characterized in that the detector is designed to generate a single signal representing a combination of reflected ultraviolet light and fluorescent light, wherein the comparison means is for comparing said signal with a signal representing the detected reference light level.  13. The device according to p. 12, characterized in that the detector contains a first sensor for detecting reflected ultraviolet light and fluorescent light and a second sensor for detecting a reference light level.  14. The device according to claim 1, characterized in that it is designed to detect counterfeit banknotes.  15. The device according to claim 1, characterized in that it comprises shielding means for shielding the detector from external illumination.  16. The device according to clause 15, wherein the shielding means is a cover in which there is a gap through which the banknote can be placed on the window through which the specified ultraviolet light.  17. A method for determining the authenticity of a test object, which consists in irradiating the test object with ultraviolet light and determining authenticity based on the detected fluorescence of the test object and the ultraviolet light reflected from it, characterized in that during testing, the device and the test object are manually positioned relative to each other friend and decide on authenticity by measuring ultraviolet reflection, the value of which is determined by the absolute reflection Yelnia ability of the test object.  18. The method according to 17, characterized in that they determine the authenticity of banknotes. Priority on points:
01/09/93 - according to claims 1 - 11, 17 - 18;
04/15/93 according to paragraphs 12-16.

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