NO138302B - DEVICE FOR COMPARATING THE SPECTRAL REMISSION FROM COLORED SURFACES - Google Patents

Description

The present invention; vedrbrex a device; for comparison ay the spectral remission from colored surfaces, especially for authenticity testing. of notes and other securities, including; a measurement request for exploration, of, a plurality of measurement values from the same areas, at. one. pr6 road jen's tooth, and an original, where- must-le^.er;di.ene. includes, only, et. narrow spectra!.^ area., as well as an assessment device for or. comparison; of,< pro ve measurement value one med. the? fira, the original taxed: reference values.

As is well known, the human city is not able to determine which spectral colors a color stimulus is composed of.

It is therefore possible that colors with different spectral composition

ning gives exactly the same color sensations. The reproduction of a particular color is relatively easy as long as only a small physical impression is required. It is much more difficult to reproduce a color with exactly the same spectral distribution. When comparing two colours, for example when testing the authenticity of banknotes, a complete spectral analysis therefore requires a very recent instrument.

Devices for comparing the spectral emission from colored surfaces are known. However, they are expensive and require operation and an evaluation of the measurement results with the help of qualified professionals.

A device is also already known which automatically performs a spectral analysis of a document and makes a yes/no choice.

In this way, the same place on the sample object and an original are simultaneously illuminated with a light source with a narrow spectral range, the light reflected from the sample object and from the original is measured using two light detectors and the two measurement values are compared with each other. In connection with this, the same measurement is repeated within two further narrow spectral ranges. The document is judged to be genuine if, in all three comparative measurements, the difference between the sample measurement value obtained from the sample object and the reference measurement value obtained from the original does not exceed a predetermined value.

Since soiled specimens absorb significantly

more light than new, clean documents, then with the known device the tolerance limits used in the yes/no choice must be chosen relatively wide, which adversely affects the reliability of the test or examination. Furthermore, there is a risk that the measured value may be distorted due to aging phenomena in the light sources or the two light sensors.

The purpose of the invention is to provide a simple and yet extremely reliable device of the type mentioned at the outset, which neither the aging phenomenon of the felt organs nor of the light source or soiling of the test bodies can cause a wrong choice. According to the invention, this is solved by providing an electronic division link, which forms the quotients between the individual test measurement values and the associated reference measurement values, that a link is provided for determining the spread that the quotients show, where the quotients are divided into classes by this link and where, moreover, the outputs of two adjacent classes are connected to a pulse counter, which only emits an output signal at a predetermined number of counting pulses, that the outputs of the pulse counters are connected to a common OR gate for outputting a YES/NO signal, and that each class is assigned a window comparator connected after the division device.

The specified design of the assessment device prevents soiling of the test object from giving false measurement results. The proposed design of the device's optical parts, together with the new way of working of the assessment device, means that the aging phenomenon of the light source and the sensors cannot have a harmful effect. Moreover, the specified design of the optical parts enables the use of a particularly simple connection for providing the quotients between the individual sample values and associated reference values.

The invention shall be described in detail below with reference to the attached drawing, in which an embodiment of the invention is schematically shown as an example. Fig. 1 shows a principle core for a device for comparing the spectral emission from colored surfaces. Fig. 2 shows a connection core for a connection for forming the quotients between individual sample values and associated reference values.

In the embodiment according to fig. 1, a light source 1 is shown, the spectrum of which includes the entire wavelength range to be analyzed and which casts light on a movable diffusion filter (transition filter) 4 through a lens 2 and an aperture 3. The filter 4 is covered with a mask 5 which exhibits a majority openings 6. Depending on the filter's 4 position, this reaches wood

measurement is moved continuously or step by step in the direction of the arrow

light falls through one of the openings 6 onto one of two light guides 7, 8. Thus, it will be understood that the filter 4 and the mask 5 move simultaneously past the opening through the aperture 3. However, it should be noted that the filter over its entire surface is preferably of one and the same nature, which is why it is not so important in and of itself that the filter is movable, but all the more important that the mask 5 is displaceable. The light guide 7 directs the light beam at a selected place on an original 9, and the light guide 8 at a corresponding place on a sample object 10. Two further light guides 11, 12 guide part of it from the original 9 resp. from the test object 10 remitted light to one and the same sensor 13.

The felt member 13 is connected to the input 14 of a coupling 15

for forming the quotients between individual sample values and associated reference values, which connection output 16 is connected to a maximum value memory 17. For synchronizing the connection 15 and for controlling the memory 17, a light sensor 19 is arranged which is connected to a control connection 18

and which receives synchronizing light pulses over a conductor 20 in dependence on the movement of the filter 4. An output 21 in the control link 18 is connected to a synchronization input 22

at the connection 15 and a further output 23, a control input 24 of the memory 17 is connected.

After the memory 17, n window comparators 25 are connected -

29, each of which is assigned to a predetermined class of output magnitudes from the maximum value memory and emits a signal when said output magnitude falls within the relevant class. With 30 - 33 is denoted (n - 1) pulse

counters. Each one of these pulse counters is connected to the two outputs of two adjacent comparators 25 - 29. The outputs from the pulse counters 30 - 33 are connected to a common OR gate 34.

The described device works in the following way:

When the filter 4 moves in the direction of the arrow, it reaches first

first of the apertures 6 that of the original 9 leading

the light channel. This is illuminated with a light beam with the mean wavelength. In connection with this, light falls on the sample object 10 through the same aperture opening. The same process is repeated with the wavelengths X^, X3 ... At f the holding device 13

occurs the signal sequence Ir ( X[j ,' ip ( , i'r (\2) , Ip (X2> where Ir means a reference value given from the original 9 and

Ip one from the sample item 10 emitted sample value. These measured values correspond to the emission from the original and the sample within the present spectral range.

The connection 15 forms the quotient from each pair of measured values

where k is a constant and means the relevant mean wavelength of the associated spectral range.

When the quotient is formed, the aging phenomenon of the light source 1 or of the sensing element 13 cannot affect the measurement result.

When the original and test object closely correspond to each other within the beam length range relevant for measurement, the constant value q (>sj = k) is obtained for q.

The dirt layer on a banknote usually behaves like a gray filter, i.e. it does not absorb selectively. When testing a genuine but soiled banknote with a device according to the invention, the result q ( >s. ) = k oe, is thus obtained, where a means the absorption capacity of the dirt layer.

The criterion of authenticity thus does not apply to the quotient value itself, but to the constancy of successive quotients q As in practice real test objects also show differences in relation to the original used and the contamination does not always behave like an idealistic gray filter, real test objects also give a certain range of dispersion on the obtained quotients. With the help of the device connected after the connection 15, it is tested whether the deflection area lies within predetermined limits. The output signals from the connector 15 are fed to the memory 17. The maximum value of these, as a result of the movement of the filter 4, non-square-shaped signals are stored in the memory

17 to the next following signal occurs and is supplied to the comparators 25 - 29. Each one of these comparators emits a pulse when their input signal corresponding to the quotient q falls within the same assigned class. The classes are chosen, for example, in accordance with the following form.

The width of a class is preferably proportional to the mean value of the class.

The pulses emitted from the window comparators 25 - 29 are counted

in the pulse counters 30 - 33 in such a way that each counter an-

the number of quotients falling in two adjacent classes.

In the case of an uncontaminated specimen corresponding to the original, all the q-values fall within the class given by the comparator 29, whereby after the measurement is finished, a pulse number corresponding to the total number of individual spectral measurements is stored in the counter 33. A real, slightly soiled test item gives smaller q-values, the number of which is counted by one of the pulse counters 30 - 32. The test is considered correct when, for example, 90% of all quotients fall within the same or two adjacent classes, i.e. when, after the measurement has been completed, a of the counters 30 - 33 have achieved a predetermined pulse number. In this case, a signal appears at the output of the counter in question which opens the OR gate 34, whereby the YES choice is displayed in a manner that is not clearly apparent from the drawing.

In the case of a sample whose spectral remission does not correspond to the same one from the original, a corresponding spread of the q-values is achieved, whereby none of the counters 30 - 33 achieves the counter state necessary for the YES selection. A very heavily soiled specimen which, although it is true, emits constant q-values, but which lie below the predetermined classes, likewise fails to provide a YES choice either. This also applies to a specimen with excessively large q-values.

The described device can be varied in a number of different ways. As a filter device with a plurality of filter areas with different narrow spectral areas, instead of a masked diffusion filter, a rotating system with discrete individual filters can be used. Appropriate for this is a drum on

whose mantle surface the filters are arranged and inside which a light source is arranged. Instead of light guides, a mirror filter can also be used which alternately casts the light onto the original

and on the sample object above the filter device as well as deflects from the same remitted light to the sensing device.

In that the sample measurement value and a corresponding reference measurement value

do not lie simultaneously in time but come one after the other, it becomes possible to use a particularly simple division or quotient method. For example, the so-called double integration method can be used, where a capacitor is charged for a constant time with a current that is proportional to the first measurement quantity and discharged again with a current that is proportional to the second measurement quantity. The discharge time then corresponds to the quotient between the two measured values.

A further advantageous possibility appears from fig. 2.

The inputs 14 of the one in fig. 2, the coupling 15 shown is connected via a resistor 35 to a first input 36 of a differential amplifier 37, to the output 16 of the switching device as well as a grounded adjustable resistor 38. A second input 39 of the differential amplifier 37 is connected to a differential voltage UR. From the output of the differential amplifier 37, a control circuit goes via a diode 40 to the control electrode 41 of the adjustable resistor 38. A switch 42, whose control electrode forms the synchronization input 22 of the connection in question 15 is located in parallel with a capacitor 43 connected between the control electrode 41 and ground.

The resistors 35 and 38 form a regulated voltage divider. By

discharged capacitor 43, the resistor 38 is very high-resistive.

When a signal 1; occurs at the input 14, the capacitor is charged

the sator 43 until the voltage Ug at the input. 36 to for-

the stronger 3 7 reaches the value UR. The resistor 38 is thereby set in such a way that U .e = U^iv .. When the signal I in the rig disappears, the diode 40 prevents a discharge of memory

the capacitor 43, whereby the division ratio of the voltage

the divider 35, 38 which has been adjusted depending on the magnitude of the signal I is retained. When the signal I up-

r p

three, a voltage is obtained at the output 16 which corresponds to the quotient

either q = _jd .

IN

r

In connection with this, the control link 18 emits a pulse at

the synchronization input 22. Thereby the switch 42

conductive for a short time and the memory capacitor 4 3 is discharged again.

Claims (7)

1. Device for comparing the spectral remission from colored surfaces, especially for the authentication of banknotes and other securities, including a measuring device for exploration of a majority of measurement values from the same areas at a test object and an original, where the measurement values include only a narrow spectral range, as well as a judgment device for comparison of the sample measurement values with those from the original given reference values, characterized by that an electronic division link (15) is arranged, which forms the quotients between the individual test measurement values and the associated reference measurement values, that one has been arranged coupling (25-33) for determining the spread as the quotients shows, where the quotients are divided into classes by this connection and where, moreover, the outputs of two adjacent classes is connected to a pulse counter (30 ~ 33), which only emits a output signal at a predetermined number of counting pulses, that out the corridors from the pulse counters (30 - 33) are connected to a common OR gate (34) for outputting a YES/NO signal, and that each class is assigned one after the division device (15) is connected window comparator (25-29). 2. Device as specified in claim 1, characterized in that the dividing device (15) includes a regulated voltage divider (35, 38) connected between the input circuit (14) and the output circuit (16), which is connected to a first input (36) in a differential amplifier (37), that the differential amplifier's (37) second input (39) is connected to a reference voltage (UR), and that its output is connected to a storage capacitor (43) and a control input (41) for the voltage divider ( 35, 38). 3. Device as specified in one of the preceding claims, characterized in that two light channels (7, 11; 8, 12) emanating from a light source (1) are arranged, which in this way lead to a single measuring sensor (13) between the light channels and the division device (15), that this is given alternately a test measurement value and an associated reference measurement value. 4. Device as stated in claim 3, characterized in that the light channels (7, 11; 8, 12) are made up of light conductors. 5. Device as specified in claim 3 or 4, characterized in that in the light channels (7, 11; 8, 12) a continuously or stepwise movable filter device (4,5) with several filter areas (6) with different, narrow spectral range. 6. Device as stated in claim 5, characterized in that the filter device consists of a continuity filter (4) with a mask (5). 7. Device as stated in claim 6, characterized in that the filter device consists of a rotating system with discrete, single filters.