EP1810252A1

EP1810252A1 - Merchandise scanning register

Info

Publication number: EP1810252A1
Application number: EP05787398A
Authority: EP
Inventors: Reinhard Plaschka; Alfred Schmidt; Martin THORBJÖRNSON
Original assignee: Giesecke and Devrient GmbH
Current assignee: Giesecke and Devrient GmbH
Priority date: 2004-09-21
Filing date: 2005-09-19
Publication date: 2007-07-25
Also published as: WO2006032434A1; US20080061143A1; DE102004045708A1

Abstract

In order to improve security when, in trade, payment is made with cash, a merchandise scanning cash register is provided with a two-channel scanner. The first channel operating with a first wavelength in the visible region of the spectrum serves both for detecting barcode information (5) applied to the merchandise (4) as well for detecting a value coding (7) of a banknote (6) presented for paying for the merchandise. The second channel of the scanner (2) serves to verify the authenticity of the banknote (6) and operates in the IR region of the spectrum.

Description

Goods checkout scanner

The invention relates to a method for increasing the security in the payment with cash in the trade and in this context a Waren¬ scanner cash.

Warenscannerkassen are used commercially to read auf¬ brought on the goods information-conveying codes, due to which the goods in the cash register, among other things, a purchase price is assigned. Most of the scanners connected to the cash register are surface or bar code laser scanners, which usually work with visible red light.

In DE 101 07344 A1, it is proposed to include such scanner cash registers in a method for monitoring national and international cash transactions. For this purpose, all banknotes are provided with an identifiable and unchangeable identification barcode which is read for each payment by means of the laser scanner of the cash register. The code contains, in addition to the serial number of the bill, further data on currency, payment value, issue date, etc. as well as a check digit for checking read errors. At each seat change, the read encoding is compared with a record stored in a central database for this encoding. In this way, the emergence of stolen bills worldwide can be recognized immediately. As a side effect is achieved that the counterfeiting of banknotes is pointless, as Falsifikate be recognized immediately, because it entwe¬ the detected coding already a second time or because the Codie¬ tion is not recognized. Since the value of the bill in the code is contained as a further side effect that the bill of the customer and the change can be automatically entered and discharged in the cash register.

It is not foreseeable whether such a central monitoring system can be implemented in the foreseeable future, since all circulating banknotes must be provided with a corresponding coding for this purpose. Moreover, it is relatively easy to imitate a corresponding coding, by copying or other printing processes and thus to produce such counterfeits that the scanner does not recognize. In addition, the detection of duplicates requires a considerable amount of on-line network connections with continuous synchronization of very large amounts of data.

It is therefore an object of the present invention to provide a simple method for increasing the security of cash payment in commerce and low-cost technical means for carrying out the method, which can also be applied to existing banknote designs without barcodes.

This object is achieved by a method and a goods scanner cash register with the features of the independent claims. In dependent claims dependent advantageous developments and refinements of the invention are given.

Accordingly, it is provided to scan the banknotes submitted for payment of the goods by means of two different wavelengths. For this purpose, the scanner connected to the cash register has two measuring channels. The first measuring channel with which the goods information, that is to say bar codes, which are attached to the goods are also preferably used at the same time to recognize the value of the banknotes presented for the payment of the goods. In this case, laser light in the visible red spectral range is preferably used and the laser radiation reflected from the banknote is detected and evaluated.

For this purpose, the laser beam is deflected, for example, by rotating mirror and tilting mirror so that it covers the largest possible area at different angles and thus there is a high probability of recognition of codes or other typical signal progressions of bank notes.

The value of the banknote results from a value coding, which in the simplest case is formed by the motif print image that is visible to the viewer and that is unambiguous for the denomination of the banknote, since, due to the motif print image, the scan results in a defined course of the scanning a characteristic local reflection pattern. Instead of or in addition to the motif printed image, the value of the banknote can also be determined by means of a separate coding, e.g. a separate barcode.

As a result, it is not necessary to adapt the scanner with respect to the first measurement channel in order to record the value of the banknote. Only the evaluation device of the goods scanner cash register has to be upgraded to identify the banknote value. The second measuring channel is added to the conventional goods scanner cash registers. It works, for example, in the IR range and serves above all to check the banknotes for authenticity. For most banknotes contain as security against counterfeiting at least a verifiable by IR radiation authenticity feature, that is, a feature that is not conspicuous in Ta¬ geslichtlichtrahlung, but with respect to the reflection and / or absorption properties in the first and second Measuring channel clearly distinguishes. In this case, in addition to the addition of the second measurement channel, the evaluation device should also be upgraded in order to be able to appropriately evaluate the authenticity feature detected by means of the second measurement channel.

Preferably, the same mirror system for the deflection of the illumination beam of the second measurement channel is used for this second measurement channel as for the first measurement channel, so that the signals of the two measurement channels are uniquely associated with each other and can be evaluated together. The authenticity feature of the banknotes thus verified can not be forged by simple methods, in no case simply by copying.

Thus, by simply upgrading existing merchandising cash registers with a two-channel scanner and an extension of Auswertoft¬ goods realize a goods scanner cash register with the addition of the goods attached to the bar codes and the banknotes for payment of the goods recorded value and simultaneously checked for authenticity can be. Upon recognition of a valid banknote, the commodity scanner cashier gives a signal from, for example, acoustically, and the value is automatically ver¬ to the cash register wei¬. This eliminates the need to manually enter the value of Bankno¬ th in the cash register, and the protection against counterfeiting is also significantly improved. It is ensured that no counterfeits are accepted and that no more fakes are issued than change.

The method and the correspondingly adapted goods scanner cash registers are particularly suitable for checking the authenticity of banknotes which have an IR cut in the motif print image, i. Have IR-absorbing and IR-reflecting areas in the motif print image. By comparing the position of these IR-absorbing and IR-reflecting regions relative to the position of the value coding detected by means of the first measuring channel, ie the motif-printed image itself, the security against counterfeiting can be additionally increased. In addition, because of the tight tolerances, the laser provides very high accuracy in terms of the spectral evaluation of the reflected signals, e.g. by an evaluation of absolute or relative reflection values of the two measurement channels. The IR authentication feature can form a bar code within the motif print image. However, it can also be a code that is completely independent of the motif print image and, if appropriate, has a fixed local relationship relative to the printed image.

The invention will be explained below by way of example with reference to the accompanying drawings. Show:

1 shows a goods scanner cash register with digital cash register and connected scanner, -. 2 shows a banknote in plan view with superimposed scanning lines, and

FIG. 3 shows the time profile of the reflectance intensities detected during scanning at two wavelengths λi and λi.

FIG. 1 schematically shows a goods scanner cash register comprising a digital cash register 1 with screen and keyboard and a scanner 2 connected thereto. Products 4 are first guided past the goods scanner cash register on a conveyor belt 3. Information-conveying bar codes 5 attached to the products 4 are read by the scanner 2 and fed to the digital cash register 1. On the basis of these Warenin¬ formations a purchase price sum is calculated by the cash register and indicated for example by display on the screen of the cash register 1. Subsequently, a banknote 6 submitted for payment of the goods 4 is scanned with the same scanner 2, in order on the one hand to record a value coding of the banknote and, on the other hand, an authenticity feature of the bank note.

The scanner 2 in Figure 1 is shown as a hand-held scanner. Instead, it is also possible to use a flat bed scanner integrated into the transport system in the usual way or a circular scanner permanently installed next to the transport system, on which the banknote 6 and the goods 4 are passed.

The scanning of the banknote 6 is explained below with reference to FIG. 2 in the further detail. The scanner 2 comprises two measuring channels for checking Reflective properties of the banknote 6 at two mutually different wavelengths λi and Xz. While the one wavelength λi lies in the visible spectral range, preferably in the visible red range, and the detection of both the commodity information on the basis of the barcode 5 and the value encoding of the banknote 6 serves, the second wavelength λz lies in the infrared range and serves for checking the authenticity Accordingly, the scanner 2 is equipped, for example, with laser diodes which radiate in the relevant wavelength ranges λ i and X z, and is equipped with precisely aligned detectors which generate the remission radiation λ i and Xz localize. The detectors for detecting the remission radiation λ.sub.i and X.sub.z are here aligned with measuring points or measuring tracks which are immediately adjacent, and preferably superimposed on one another. With the remission measurement in the visible wavelength range λi, the motif print image 7 of the banknote 6 is detected and deduced from the characteristic local intensity curve Iχi (FIG. 3) to the nominal value of the banknote. This takes place in an evaluation device of the cash register, in which current banknote parameters are stored for comparison with the respectively measured values recorded.

The motif printed image 7 of the banknote 6 moreover has an IR cut as a feature of authenticity, that is to say it has IR-absorbing and / or IR-reflecting regions in a characteristic local distribution in the motif print image 7. The remission measurement of the IR radiation Xz then gives a likewise characteristic local intensity profile Iχi (FIG. 3), an¬ hand thereof by comparison in the evaluation unit of the cash register 1 the authenticity of the banknote 6 is checked with reference values stored there.

By evaluating a plurality of successive scans of the banknote, which detect further areas of the banknote due to the movement of the rotary and / or tilting mirror, the evaluation security can be improved both with regard to the secure recognition of genuine banknotes and the rejection of counterfeit banknotes.

In addition, a position comparison of the local intensity profiles I χi (x), I χ2 (x) can be carried out in order to additionally increase the security against counterfeiting. An additional position comparison is particularly useful if the checked IR authenticity feature does not have an IR cut in the motif print image, but e.g. a simple IR barcode which is independent of the motif print image and in which the local intensity profile of the remission radiation varies substantially only between a maximum value and a minimum value.

The rating of the banknote is particularly simple if it is recorded in a specific defined position relative to the scanner. In particular, in the case of a built-in flatbed scanner or all-round scanner, this can be done, for example, by placing the banknote in a specific area of the scanner window. In the case of a handheld scanner, this can be done, for example, by scanning the banknote longitudinally through the center of the banknotes at a certain distance. In these cases, the signals can be reproduced very well and evaluated and analyzed with little effort. But it is also possible in principle to assess the banknotes in any position relative to the scanning beam or the scanner safely. As a rule, the signals for possible variations with regard to the angle and the size (or the distance) of the banknote relative to the scanner are to be examined for this purpose, and banknotes-typical signals are to be extracted by suitable algorithms. It is advantageous in this case if the edge of the banknote is not covered or supplies a defined pattern, so that the entry and exit time of a deflection beam in the intensity curves can be easily found.

In principle, this method can also be used if the banknote is kept free in the room, whereby it does not necessarily have to be scanned in the flat state by the scanner. For this purpose, the possible position of a banknote is first of all determined from the entry and exit data and then the measured signal courses compared with the stored reference data for the same location.

As an extension of the method described above, it is also possible to check the wear and tear condition of the banknotes, such as e.g. Folded banknotes or those with damage (such as dog-ears) can be reliably detected.

In principle, it is also possible to evaluate other spectral color properties of the banknote instead of IR properties, for example in the far IR or in the UV range, if appropriate by evaluating fluorescent, phosphorescent or other luminescence properties of the printing inks used. This is then measured, for example, at wavelengths which are different from the luminescence-inducing wavelength and in which luminescence radiation occurs. In addition, especially in the case of phosphorescent properties of the bank note, it is also possible to detect the time dependence, in particular the decay time, of the luminescence radiation.

The method is not limited to laser beams, but can basically be realized with other optical scanning systems. This makes it possible to freely select the size of the scanning point or the scanning line on the banknote and to optimize the spectral evaluation to specific wavelength ranges. It is also possible to use three or more different measuring channels, again preferably with different diode and / or photodetectors, which irradiate the banknote at different wavelengths and / or detect the light emanating from the banknote at different wavelengths.

Claims

Patent claims

A goods scanner cash register comprising a digital cash register (1), a scanner (2) connected to the cash register (1) with a first measuring channel operating at a first wavelength (λi) both for detecting information (5) attached to goods (4) coding also for detecting a Wert¬ (7) of submitted for payment of goods (4), bank notes (6) and an evaluation device for determining the value of the banknotes (4) based on the detected value of coding (7) _/ marked thereby that the scanner ( 2) comprises a second measuring channel operating at a second wavelength (λ2) different from the first wavelength (λi) for detecting an authenticity feature of the banknote (6).

2. Goods scanner cash register according to claim 1, characterized in that the second measuring channel for an IR measurement, in particular an IR reflection measurement is set up.

3. Goods scanner cash register according to claim 1 or 2, characterized in that the first measuring channel is set up for a reflection measurement in the visual spectral range, in particular with red light.

4. Goods scanner cash register according to one of claims 1 to 3, characterized gekenn¬ characterized in that the value coding (7) by a reflection pattern of the ei¬ nen viewer visible motif print image of the banknote (6) is formed.

5. goods scanner cash register according to one of claims 1 to 4, characterized gekenn¬ drew that the evaluation is set up for comparison the relative position of the Wertcodie¬ (7) detected by means of the first measuring channel to the authenticity feature detected by means of the second measuring channel and / or the evaluation device is set up for checking the state of the banknote.

6. Goods scanner cash register according to claim 5, characterized in that the authenticity feature is an IR section in the motif printed image (7) of the banknote (6).

7. Goods scanner cash register according to one of claims 1 to 6, characterized in that the second measuring channel is set up for a UV measurement.

8. Goods scanner cash register according to one of claims 1 to 7, characterized gekenn¬ drew that the evaluation device is designed to check the banknotes in ei¬ ner free and / or predetermined position and / or the evaluation is designed, the situation such. the attitude angle and or the dimensions, e.g. at least one boundary line to be able to determine the banknote.

9. Goods scanner cash register according to one of claims 1 to 8, characterized in that the first or second measuring channel is set up for a luminescence measurement and the evaluation determines whether the ge checked banknote shows a predetermined Lumineszenzverhalten.

10. Warenscannerkasse according to one of claims 1 to 9, characterized in that recorded for the irradiation of the banknote to be tested and / or

Detecting the radiation emitted from the irradiated bill the same optical components for the first and the second measuring channel ver¬ be used.

11. A method of increasing security in cash payment in commerce comprising the steps of:

Detecting goods information (5) attached to goods (4) by means of a scanner (2) operating at a first wavelength (λi),

- passing the information to a digital cash register (1),

Calculating and indicating a purchase price sum by the cash register (1) on the basis of the commodity information (5) and

- Detecting a value coding (7) of a banknote (6) submitted for payment of the goods (4) by means of the scanner operating with the same first wavelength (λi), characterized by the further step of detecting a authenticity feature of the banknote (6) by means of the same scanner (2), but at a different wavelength (λ2) from the first wavelength (λi).

12. The method according to claim 11, characterized in that the step of detecting the authenticity feature comprises irradiating the banknote (6) with IR radiation (λ2) and measuring the IR radiation reflected from the banknote (6).

13. The method according to claim 11 or 12, characterized in that the step of detecting the value coding (7) irradiating the banknote (6) with radiation (λi) in the visual spectral range, in particular with red light, and measuring the of the Banknote reflects reflected radiation of the visual spectral range.

14. The method according to claim 13, characterized in that the step of detecting the value coding (7) comprises detecting a reflection pattern of the visible to a viewer motif print image of the bill (6).

15. The method according to any one of claims 11 to 14, characterized by the further step of comparing a relative position of the value coding (7) and the authenticity feature on the banknote (6).