DE19701513A1 - Test system for identifying security markings - Google Patents

Abstract

The unit is used 1 to control a pair of transmitters 2 that provide narrowband signals a1,a2 that have wavelength differences. The signals are directed at the surface containing the security marking 3 and the signal reflected from the surface is transmitted b to a detector 4. This connects with a processor that identifies the signal.

Description

The present invention relates to a test method and a testing device for the authenticity control of Authenticity marks, such as those used as color marks on objects, especially printed on documents, securities, and the like are provided.

It is known from the prior art, in particular Printed matter, such as preferably securities, banknotes and Like. To provide color features, in particular printing, by means of which one is awarded to them Authenticity feature the authenticity of the item in question can be checked.

From DE-C-3020652 is known, specifically selected / manufactured printing inks for authenticity features / brands to provide or use. The z. B. on a Document printed on the test sample color samples using a xenon flash lamp illuminated. Of these colors is due to the wavelength such irradiation luminescent / fluorescent radiation emitting / reflecting. This occurring Radiation is in a detector device Spectral analysis and based on the spectral analysis result decided whether this irradiated brand has the authenticity feature. Sadly it is Counterfeiters relatively easily possible for such inks analyze dyes used for authenticity features and imitate. If this is achieved, the described can Authentication system undermined and practically worthless  be made, although besides these specially manufactured ones Inks with complex optics with different Interference filters and the like for the respective Test facility has been used.

Accordingly, it is an object of the present Invention, an operating method for such Testing facility to find that without particularly complicated Optics get along and with conventional electronic Components can be realized in a simple manner. This Device should preferably be low in weight so that it especially to be used as a portable test device.

This object is achieved with the method according to claim 1 or the testing device according to claim 4, 5 in Continuing education solved according to respective subclaims.

The invention is based on the finding that through a only narrowband radiation / excitation of the (color the) authenticity mark in at least two of each other different (at most slightly overlapping) Wavelength ranges with a definable wavelength distance spaced respective middle wavelengths characteristic intensity values of that for this color characteristic spectrum curve, d. H. the dependence of Intensity from the wavelength, or for the respective Average of the respective narrowband Wavelength range, can be determined. From measurements in several, at least two such adjacent narrow Wavelength ranges can then be selected Slope value of the characteristic spectrum curve mentioned determine this color and check it for authenticity.

Further explanations of the procedure go from the following description to according to the invention Test facility working in their respective Design.  

Recording the characteristic spectrum curve of a Color in itself is common in another context and therefore too using devices are known. As above mentioned, is used for the spectral analysis one color either different wavelength selective or tunable with regard to the wavelength selection optical devices on at least the transmitter or Reception side.

In contrast, the invention is that of the invention underlying simplification harnessed, individual to provide selective transmission wavelength ranges and To use detectors that are not necessarily are wavelength selective. The one working according to the invention Test facility is designed or is closed operate that the intended emission of radiation different narrow wavelength ranges according to one preferred variant of the test device only time-division multiplex, d. H. never for the different at the same time Wavelength ranges. In the invention different radiation sources, preferably Luminescent diodes, each at different wavelengths Emit radiation only in narrow wavelength ranges, used, that can be switched in a time-divisional manner in a simple manner. Therefore, one can in this variant of the invention Use detector device that is not wavelength selective Must have property. It's even an advantage, not one to use selective detector provided for all Wavelength ranges is equally sensitive. This saves corrections.

Is the test device working according to the invention trained that they selected time-division broadcasting given various narrow wavelength ranges executes and with the detector arrangement that of the irradiated authenticity feature at the respective time  (again) outgoing radiation falling into the detector equally quantitatively, is the respective The steepness of the measurement signal curve as a predefinable authenticity feature reliably verifiable. This is with the invention can be carried out correspondingly with little technical effort. With the Inks can be different from each other, i.e. H. a real color with the authenticity feature, from another, color not having this authenticity feature, be distinguished. This also applies if the at Invention used broadband detector integrally for the whole recorded spectral range for both colors has matching detection properties.

Further explanations of the invention are based on the figures given the additional disclosure content to the invention are.

Fig. 1 and 1a respectively show a basic diagram of a device according to the invention.

Fig. 2 shows a graph of spectral reflectance values of (printing) inks.

Fig. 3 shows a scheme for local distribution of color marks and their testing.

Fig. 4 shows an example of the optics of the device.

Fig. 1 shows the principle of a structure and operation of a test device 10 of the invention in allgemeinster form. 1 designates a control unit with which time-division multiplexing can optionally control one of the two transmitters 2 ₁ and 2 ₂ for emitting radiation. When the transmitter 2 _{1 is} activated, it emits narrowband radiation a ₁ . When the transmitter 2 ₂ is activated, the radiation a _{2 is} emitted from it. The two radiations a ₁ and a ₂ differ in the mean wavelength value of their respective narrow (at most insignificantly partially overlapping) wavelength ranges. The two wavelength ranges have a distance from one another that can be predetermined for the construction of the test device. For such transmitters 2 ₁ and 2 ₂ , semiconductor luminescence diodes are particularly suitable which have relatively narrow wavelength ranges of their emission, which are available in a corresponding selection and which can be operated easily in a time-multiplexed manner, ie in a time-selective manner.

The radiations a ₁ and a ₂ are both aligned to one and the same surface element of an authenticity mark 3 . Radiation b is emitted by this authenticity mark 3 both when irradiating a ₁ and when irradiating a _{2, which} radiation is collected by a detector 4 . Depending on whether it has been excited by radiation a ₁ or a _2, this radiation b has a different wavelength (different wavelength range). However, since the detector 4 is broadband, regardless of whether irradiation a ₁ or a _{2 has} occurred, it provides a respective detector signal which corresponds to the detected intensity of the radiation b received (at the corresponding time).

The output signals of the detector 4 reach an evaluation unit 5 . This is communicated via the connection 6 by the control unit 1 , which transmitter 2 ₁ or 2 ₂ emits radiation at the moment, namely at the time the detector signal from the detector 4 is received in the evaluation unit 5 . In this way, the received signal of the detector 4, which came to the evaluation 5 at a certain point in time, can be assigned to the respective transmission radiation a ₁ or a ₂ .

The connection 6 of FIG. 1 can be omitted if only two transmitters ( 2 ₁ and 2 ₂ ) are assigned to each detector ( 4 ).

The basic arrangement of FIG. 1 can also be equipped with further wavelength-selective transmitters (still other wavelength ranges) such as the transmitters 2 ₁ or 2 ₂ , which likewise irradiate the area element of the authenticity mark in a time-multiplexed manner and likewise give rise to the emission of radiation b. This radiation then received in the detector 4 can also be assigned to the respective transmission wavelength range by means of the signal of the line 6 .

In spite of non-wavelength-selective detection, the invention makes it possible to unambiguously assign the instantaneous detector signal to a specific wavelength range (the radiation a ₁ or a ₂ or...) Due to the time multiplex operation in the evaluation unit 5 . The measurement signals of the detectors are evaluated by the evaluation unit 5 according to their DC component and their AC component in the signal. From this, the courses in the spectrum of the radiation b in the relevant wavelength range can be assessed. On the basis of these dynamically recorded courses, a result-dependent output takes place by a task unit 7 .

Fig. 2 shows for three colors, the respective degree of reflection depends on the wavelength. Here, curve 21 is the one that belongs to a specially selected black color that can be used as a selected authenticity feature. Such a second curve 22 of a corresponding second color (for a second / alternative selectable authenticity feature) is also specified. Curve 222 is the corresponding curve for another (usual) printing ink. In FIG. 2, the central wavelengths of 20 _1m, 20 _2m of the narrow wavelength regions 20 ₁ and 20 ₂ of the radiations a ₁ and a ₂ are marked. FIG. 2 shows how different the reflection values, ie the respective intensity values of the radiation b, are when the respective color (time-multiplexed according to the invention) is irradiated with radiation a ₁ and radiation a ₂ . Measured values 23 and 24 are obtained for the color (an authenticity mark) with curve 21 . These measured values represent the authenticity feature hidden in this color of curve 21 , which can be checked for the presence with the device of the invention. The second color with curve 22 gives completely different reflection values 123 and 124 for the wavelength ranges of the radiation a ₁ and a ₂ as a second alternative authenticity feature . For the third curve 222 of another printing ink one obtains e.g. B. the reflection values 223 and 224 . From the respective value pairs 23 and 24 , 123 and 124 as well as 223 and 224 , the respective mean slope between the wavelength values 20 ₁ and 20 ₂ is obtained for the respective curve 21 , 22 and 222 . These gradients of these curves clearly differ from one another. It is thus possible not only to distinguish the slopes of curves 21 and 22 as authenticity features from those of curve 222 of a normal printing ink, but also to distinguish those of curves 21 and 22 from one another as authenticity features that differ from one another.

A test device according to the invention can be used Color of the authenticity feature adjusted in the ultraviolet, visible and / or infrared spectral range working operate.

The individual channels 2 ₁ , 2 _2,. . . the transmitter arrangement 2 are spatially arranged as close as possible in favor of a simplified structure with regard to the optical paths. For a detector 4 , which consists of several individual detectors 4 ₁ , 4 _2,. . . there is a similar structure is advantageous.

Another advantageous variant of the test device according to FIG. 1 is one according to FIG. 1a with one for the individual wavelength ranges 20 ₁ , 20 _2,. . . the radiations a ₁ , a _2,. . . selectively sensitive detector arrangement 4 ', namely instead of the non-selectively operating detector arrangement 4 of FIG. 1. This selective detector arrangement comprises e.g. B. correspondingly many individual selective detectors 4 ' ₁ , 4 ' _2,. . ., which individually send their signal to the evaluation unit 5 . In this variant, the emission of the selective radiations a ₁ , a _2,. . . done at the same time. In response to this radiation, the selective radiation b ₁ , b ₂ ,. . . from the authenticity feature to the detector arrangement and are there selectively by the individual detectors 4 ' ₁ , 4 ' _2,. . . recorded and converted into electrical signals for the evaluation unit 5 . The selectivity of the individual detectors 4 ' ₁ , 4 ' _2,. . . can be caused by filters or based on the inherent selectivity property of the individual detectors. The connection 6 of FIG. 1 can be omitted in the variant of FIG. 1a.

According to the test result, which can be obtained by means of a test device operating according to the invention, a signal is sent to a unit 7 , e.g. B. to peripheral devices, such as a printing unit, to locks or locks and the like for driving the same. This unit 7 can be used to process the results of the evaluation for control, signaling or alarming via z. B. electrical, optical and / or acoustic outputs. The evaluation results can also be saved as data and / or forwarded to central data processing.

With the invention, a local selection, based on a predetermined geometric arrangement of authenticity marks, can also be carried out, in particular as an additional measure of the authenticity check. To this end, FIG. 3 (as an example) in two area-uniform distance from each other on z. B. a ticket 32 attached authenticity stamps 30 ₁ , 30 ₂ with authenticity feature according to the invention. In a test device 10 according to the invention, when inserting or pushing through (arrow 35 ) such a ticket through the optical part 11 of the test device, the number of these authenticity tags corresponding to the number (in this case two) of signals from the evaluation unit 5 , and only if authenticity is present of these authenticity marks.

As a further increase in the precision of the authenticity check, it can be provided that these two authenticity marks 30 ₁ , 30 ₂ (and possibly other such authenticity marks) also differ from one another. For example, the slopes of the spectrum curves 21 , 22 (see FIG. 2) to be determined as predetermined authenticity features can be selected differently for these two (and also for further) authenticity marks. When pushing through or checking such a ticket, such measured values must then be determined one after the other, precisely by the same transmitter / detector arrangement 2 and 4 of the checking device 10 , and precisely in the sequence specified on the ticket result which correspond to the predetermined different slopes of the spectrum curves of the individual successive authenticity marks.

Such an embodiment of the test device according to the invention want to outsmart with fake authenticity stamps practically hopeless because the authenticity features in the Authenticity marks are hidden, d. H. within z. B. black Color otherwise indistinguishable as authenticity marks are positioned on the ticket and possibly also different in their authenticity characteristic (slope value) can be predetermined.

Instead of, or in addition to, time can coincide following verification of authenticity marks at the same time take place, namely if the test facility with several, in distributed measuring stands equipped with correspondingly distributed locations on the document at the same time the test process with sending and receiving the respective Carry out radiation and evaluate the result.  

As stated, the invention can be carried out in a simple manner and with simple equipment can be determined whether a z. B. black color has the authenticity feature or not, although this color of other (e.g. black) color not visibly too is different. This opens up the possibility of that Authenticity feature in other, with z. B. also black Color printed area, e.g. B. not visible to the eye, locally hidden on z. B. attach a document.

The printing inks as an authenticity feature can be on and / or in Backing material, such as. B. paper, plastic, textile or the like. As described, you can as any geometric pattern and / or also (more or less) spread all over on / over the object be. For example, the paper or the like can also be used of the color bearing the color feature.

FIG. 4 shows (for example in addition to FIGS. 1 and 3) an example of the mutual arrangement of a transmitter arrangement 2 and a detector arrangement 4 as well as the authenticity mark 3 to be placed when carrying out the authenticity check. The directional radiation a of the respective wavelength range strikes the authenticity mark 3 . The radiation b to be detected, which arrives in the detector arrangement 4 , originates from this. The further device details of this device for the authenticity check correspond to those which have already been described and explained for FIG. 1.

The invention has been described above for radiation b reflected by the authenticity mark. As an alternative to this, the method and the corresponding test device in its described variants can also work with radiation (b ') transmitted by the authenticity feature. Instead of recording the reflected radiation b with the detector 4 as in FIG. 4, when working with transmission, radiation b 'which has passed through the authenticity feature is to be collected with the correspondingly positioned detector.

Claims (12)

1. Procedure for the authenticity check of a (respective) intended / certain authenticity feature,
that is contained in a selected color spectrum of a color feature of the authenticity feature (hidden),
this authenticity feature being used for an authenticity mark ( 3 ) which is provided on objects, on documents and the like,
characterized
that radiation (a ₁ , a ₂ ,...) with at least two different, discrete radiation wavelength ranges ( 20 ₁ , 20 ₂ ,...) selected based on the color feature is radiated onto or through the authenticity feature ( 3 ) and
that radiation (b; b ₁ , b ₂ ,...) emanating from this authenticity feature ( 3 ) upon this irradiation (a ₁ , a ₂ ,...) is recorded by a detector arrangement ( 4 ) in which the respective Radiation (a ₁ , a ₂ ,...) Assigned to the respective detector reception intensities are determined and these are correspondingly supplied with electrical signals for evaluation to check the actual authenticity, for this purpose from at least two of the wavelengths (a ₁ , a ₂ ,...) each of the reception intensities to be assigned, a slope value of the curve ( 21 , 22 ) of the color spectrum of the relevant color feature is determined as an authenticity feature. 2. The method according to claim 1, in which the emission of the wavelengths of different radiations (a ₁ , a ₂ ,...) Is carried out alternately in a time-division manner. 3. The method according to claim 1, in which the emission of the wavelengths of different radiations (a ₁ , a ₂ ,...) Can be carried out simultaneously and selective separation of the radiation received in the detector arrangement (b ₁ , b ₂ ,...) is made. 4. Device for the authenticity check according to the method of one of the claims 1 to 3, this device comprising:
an optical transmitter arrangement ( 2 ₁ , 2 ₂ ,...) for emitting radiation (a ₁ , a ₂ ,...) in at least two different discrete radiation wavelength ranges ( 20 ₁ , 20 ₂ ,...),
at least one optical detector arrangement ( 4 ) with sensitivity for a total of at least these selected wavelength ranges ( 20 ) of the radiation of the transmitter arrangement,
being provided
that radiation emitted by the transmitter arrangement ( 2 ) (a) can selectively impinge on the authenticity feature ( 3 ) intended for the authenticity check, and from this as a result of this irradiation radiation (b) of the different discrete radiation wavelength ranges ( 20 ) in the detector arrangement ( 4 ) arrives where the respective reception intensity can be measured,
an electronic evaluation unit ( 5 ) with which the respective electrical signals emitted by the detector arrangement ( 4 ) are proportional to the optical radiation (b) received in the detector arrangement ( 4 ) as a result of the irradiation (a ₁ , a ₂ ,...) are processable into respective quantitative displays, and
a control unit ( 1 ) for the transmitter arrangement ( 2 ) for time-multiplexed emission of radiation (a ₁ , a ₂ ,...) of a respective one of the wavelength ranges ( 20 ₁ , 20 ₂ ,...). 5. Device for the authenticity check according to the method of one of the claims 1 to 3, this device comprising:
an optical transmitter arrangement ( 2 ₁ , 2 ₂ ,...) for emitting radiation (a ₁ , a ₂ ,...) in at least two different discrete radiation wavelength ranges ( 20 ₁ , 20 ₂ ,...),
an optical detector arrangement ( 4 ') with selective sensitivity for these selected wavelength ranges ( 20 ) of the radiation of the transmitter arrangement,
being provided
that radiation emitted by the transmitter arrangement ( 2 ) (a) can selectively impinge on the authenticity feature ( 3 ) intended for the authenticity check, and from this as a result of this irradiation radiation (b) of the different discrete radiation wavelength ranges ( 20 ) in the detector arrangement ( 4 ') arrives where the respective reception intensity can be measured selectively,
an electronic evaluation unit ( 5 ) with which the respective electrical signals emitted by the detector arrangement ( 4 '), which are selectively proportional to the optical radiation received in the detector arrangement ( 4 ') as a result of the irradiation (a ₁ , a ₂ ,...) (b ₁ , b ₂ ,...) can be processed into respective quantitative displays. 6. Device according to claim 5, the detector arrangement ( 4 ') comprises wavelength-selective detectors ( 4 ' ₁ , 4 ' ₂ ,...) Which have this wavelength-selective property. 7. Device according to one of claims 4 to 6, with an optical configuration - the radiation from the authenticity mark ( 3 ) reflected (b) can get into the detector arrangement ( 4 , 4 '). 8. Device according to one of claims 4 to 6, with an optical configuration, radiation (b ') which has passed through the authenticity mark ( 3 ) can pass into the detector arrangement ( 4 , 4 '). 9. Device according to one of claims 4 to 8, in which the evaluation unit ( 5 ) for evaluating the signals of the detector arrangement ( 4 , 4 ') is designed according to the DC and AC components of these signals. 10. authenticity mark for a method according to one of the claims 1 to 3 or for a test facility according to one of the Claims 5 to 9, which on / in the material of the object / document as Color feature is provided. 11. authenticity mark according to claim 10, the essentially all over on this material is provided. 12. authenticity mark ( 32 ), which is divided into surface elements ( 30 ₁ , 30 ₂ ,...) Is provided in the material of the authenticity mark.