APPARATUS FOR AUTHENTICATING BANK NOTES FIELD OF THE INVENTION
The present invention relates to an apparatus for verification of the authenticity of bank notes. 5. The trend towards less labour-intensive methods of distribution of merchandise using automatic vending machines for products such as gasoline, cigarettes, food, has led to an increased interest in the automatic authentication of bank notes. The advent of inexpensive microprocessors
10. now also makes it possible to implement sophisticated discrimination criteria, and provides a potential to design vending machines which will accept bank notes of different denominations and even different currencies. The increased use of vending machines, especially at higher denominations,
15. of course also increases the risk of large scale fraud, and thus emphasizes the need for adequate bank note authenti¬ city criteria. BACKGROUND ART
Differentbank note authentication methods are described
20. in Patent literature, some of which are used in vending machines now commercially available. Authentication methods and verification algorithms are known from e.g. U.S. Patent Specification 2,950,799, German Patent Specification 1774344 and Swedish Patent Specification 7606828-7. For illus-
25. tration, the main known authentication methods canbe grouped in three classes: thickness measuring, pattern recognising
and colour sensing methods.
In the first class of authentication methods, sensors are employed to measure the thickness distribution at specified portions of the bank note, correspondingtovarious 5. details on the bank note where characteristic variations in thickness are produced by the printing process, watermarks or the like. The authenticity criteria are then based on comparisons with specified standard values. The thickness is measured by mechanical or optical sensors. Mechanical
10. sensors for thickness measurements are known from e.g. BritishPatent Specifications 960,391, 963,586, GermanPatent Specifications 1,474,903, 2,423,094, Austrian Patent Speci¬ fication 329,903, Swedish Patent Specifications 337,952, 357,636, 349,679 and 7607927-6. Optical methods for
15. authenticity verification using thickness variations are known from e.g. German Patent Specifications 2005016, 2365845. Combined mechanical and optical sensors are described in e.g. Swedish Patent Specification 361,372.
The second class of authentication methods is exempli-
20. fied by U.S. Patent Specification 2,646,717, Swedish Patent Specification 196,238, where the pattern on a selected portion of the bank note is compared with a standard pattern by observing the modulation occurring when these patterns are superimposed and moved relative to one another.
25. in the third class of authentication methods, the bank note is illuminated, and the reflection and/or trans¬ mission properties of selected portions of the bank note are examined using corresponding sets of detectors, one for each portion, respectively with different spectral
30. response characteristics (e.g. U.S. Patent Specification 3,491,243). Alternatively, selected portions of the bank note are illuminated by a plurality of light sources, one for each portion, respectively with different spectral distributions, and the transmission and/or reflection
35. properties are evaluated and compared with standard values
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as a basis for the authenticity test (e.g. U.S. Patent Specifications 3,450,785 and 3,679,314) .
The following observations are made in relation to the three main classes of authentication methods described 5. above.
In so far as it is intimately related to the printing process, the thickness criterion has the advantage that it can be no more difficult to circumvent by fraudulent means than the criteria based on patterns or colours. On the 10. other hand, folds or other imperfections naturally introduced by the normal use of bank notes tend to give high rejection rates for genuine, but used, bank notes - particularly if optical measurements of thickness are relied upon. The known mechanical sensors tend to be rather expensive and 15. to require considerable maintenance to ensure correct functioning.
Of the three classes discussed, the method based on pattern recognition is probably the least satisfactory since it can be easy, by commonly available reproduction tech- 20. niques, to produce copy patterns which can be distinguished from original patterns only by microscopic examination, and extremely intricate designs have to be relied upon in an attempt to achieve adequate authentication criteria.
Colour tests of the third class probably represent 25. the best compromise between simplicity of design and satis¬ factory discrimination against fraud. With known designs of this class, however, the full potential of the spectral information has not been exploited in so far as sensors with relatively broad spectral sensitivity have been used. 30• With known apparatus in all the classes described above, only specified selected portions of the bank notes are used in the discrimination criteria. This means that a bank note has to be relatively accurately positioned in the apparatus, and the discrimination precision depends on 35. the accuracy of such positioning. Bank note printing
processes are also far from exact, and 'considerable variations of the location of print with respect to the edges of a bank note are common. Moreover, if the full logical advantages of microprocessors were to be exploited 5. in the context of such known apparatus to construct vending machines which accept several denominations and even different currencies, then compromises might have to be made with respect to the selection of the fields on the bank notes to which the criteria are to be applied, and
10. this would further adversely affect the discrimination precision. DISCLOSURE OF THE INVENTION
An object of the present invention is to provide apparatus with which bank notes can be authenticated easily
15. and conveniently yet with satisfactory precision and without an unduly high rejection rate for genuine notes.
According to the invention therefore there is provided apparatus for authenticating a bank note comprising an analyser operable to examine said note and to produce an
20. output representative of properties thereof; and a comparator operable to produce an output indicative of whether or not said note is authenticated based on a comparison of said analyser output with parameters representative of predeter¬ mined said properties; characterised in that said analyser
25. is operable to produce the same or substantially the same said output for different orientations and positioning of the same said bank note.
With this arrangement, due to the use of a mode of analysis which is independent, at least to a certain degree,
30. of the spatial orientation of the bank note, it is possible to achieve satisfactory authentication precision in a simple and convenient manner and without an unduly high rate of rejection of genuine notes.
Most preferably the said analyser is operable to examine
35. a major part of the surface of the bank note, preferably
all or substantially all of such surface, on at least one side thereof, and with a view to eliminating the effect of the spatial structure of the bank note the examined properties are preferably integrated over the entire surface area of 5. the bank note subjected to examination. Any loss of infor¬ mation due to said integration is an asset rather than a disadvantage in that it can eliminate the effect of the usual extremely detail-rich spatial structure which is difficult to process adequately. Instead the analyser 10. output can have a more easily processible information content. With the invention the bank note need not be positioned in the apparatus in an exactly predetermined manner: it may even be possible to insert the note upside down or in any orientation without impeding the accuracy 15. of the authenticity test. Moreover, it may also be possible to test different types of bank notes (different denomin¬ ations, currencies) with the same optimal accuracy.
Most preferably the analyser is a spectral analyser operable to analyse the spectral distribution of radiation 20. reflected by or transmitted through the bank note from a multi-wavelength radiation source. As appropriate the analyser may utilise a sensing arrangement responsive to selected wavelengths either in the form of a continuous interference filter or a set of discrete monochromatic 25. filters in conjunction with a sensor or sensors operable to produce electrical signals at such wavelengths. BRIEF DESCRIPTION OF THE DRAWING
The present invention will now be described in more detail with reference to the accompanying drawing which is 30. a diagrammatic representation of one form of apparatus according to the invention. BEST MODE OF CARRYING OUT THE INVENTION
The apparatus is for use in the authentication of a conventional bank note printed with a detailed colour pattern 35. usually in one or more colours and/or shades.
The apparatus can be incorporated in an automatic merchandise vending machine or used in any suitable context as appropriate. The apparatus comprises a chamber 10 to which a bank note 1 to be authenticated is fed using
5« appropriate feed equipment.
As shown in the drawing, the bank note 1 is introduced into an evaluation area 2 of the chamber 10, where it is placed against a black background 3, and illuminated by light sources 4 (such as filament lamps) with even spectral
10. distributions. The light reflected from the entire upper surface of the bank note is received by an optical sensor 5. The optical sensor 5 has a sufficiently wide optical lobe and is placed at a sufficient distance from the bank note 1 to integrate the contributions from the entire
15• surface of the bank note essentially without giving geometrical preference to any portion of the bank note. The optical sensor 5 converts the received light into spectral information of high resolution, and this information is fed in the form of electrical signals to a microprocessor-
20. based control system 6.
Several alternative embodiments of the optical sensor 5 are conceivable. In principle, a prism or diffraction grating can be used. For economical and practical reasons, interference filters are more advantageous, either in the
25* form of a continuous interference filter in which the band pass wavelength varies along the filter, or in the form of a set of discrete monochromatic filters. The electrical signals representative of spectral information are obtained either by moving the filter/set of filters in front of a
30* single detector, or by having a number of detectors behind the filter/set of filters. Depending on required wavelength sensitivity, the detectors can be silicon, germanium or lead sulphide detectors.
Even more advantageous from the economical point of
35. view is to employ light-emitting diodes (LEDs) as spectral
sensors. LEDs detect radiation in the same manner as ordinary photodiodes, but within only a narrow spectral range, approximately the same as that within which they emit light. 5. Instead of a light source with even spectral distri¬ bution and monochromatic detectors as described above, it is possible to employ a converse arrangement of monochromatic light sources and a detector or detectors with even spectral sensitivity. The light sources may be activated alternately 10. one after the other in rapid succession. With this arrange¬ ment the bank note is preferably illuminated by a set of LEDs in such a way that only LEDs of one spectral type are lit up at a time. By storing information derived from the detector in correspondence with the actuating times as the 15. LEDs, it is possible to obtain the necessary spectral information.
By a locked switch, the authentication apparatus can be made to work selectively in either of two modes: programming mode and evaluation mode. In the programming 20. mode, the microprocessor regards any new bank note inserted into the evaluation area of the apparatus as a reference, and stores the corresponding spectral information in memory. In this way a set of reference spectra for different bank notes can be derived and permanently stored. When the 25. locked switch is set to the evaluation mode, the spectrum of any new bank note inserted into the evaluation area of the apparatus is compared against the set of reference spectra in the memory. This comparison is made by a comparison algorithm, in which spectral values for the 30. test note at different wavelengths is compared to corres¬ ponding values for each of the reference spectra. In order to allow for possible soiling etc. the algorithm may contain a free normalization parameter. Since soiling and other deficiencies arising during use of bank notes, normally 35. introduce only a change in the overall reflectivity etc.,
the mean deviation obtained for genuine notes in this way is generally low, and this authentication technique provides sharp discrimination between genuine and false bank notes. Appropriate feed devices may be provided for trans- 5- ferring an authenticated bank note from the chamber 10 to a storage location whilst at the same time actuating a vending machine merchandise delivery mechanism, and for transferring a non-authenticated note to a return outlet or the like.
10♦ As already mentioned, different denominations and/or currencies can be evaluated with the same optimal accuracy with the integral authenticity criterion used with the above apparatus. This implies that the full logical potential of a built-in microprocessor can be used to enable bank
15- notes to be checked in comparison to a very large number of reference spectra for example corresponding to different denominations and currencies, for both front and back sides, for different metamers etc. In particular it is important to have adequate memory space to enable bank notes to be
20. checked for different metamers, i.e. colour pigments which look the same to the eye but have different spectral composi¬ tions. Even though most metamer differences arise as a result of fraud, the colour pigments of genuine bank notes are occassionally changed, and the programming mode in the
25- apparatus described above can provide for this to be taken into account.
The invention is not intended to be restricted to the details of the above embodiment which are described by way of example only. Thus, for example, it is possible to 0- study the transmission spectrum of the entire bank note instead of, or as a complement to, the reflection spectrum discussed above. Also, in order to obtain a superior discrimination, it is possible to use a wide spectral range for evaluation purposes, stretching from ultra-violet
35. to infra-red (190 to about 3000nm) , which range can provide
information of both colour pigment, and paper composition and structure.
For reasons of space saving, it is possible to use light guides of fibreglass or plexiglass to transport light
5.to and from the bank note and sensor/light source. In this way a much more compact embodiment can be achieved.
The light guides also provide a simple way to obtain more information from the bank note in the form of certain additional integrals over the entire bank note such as lO.fourier transforms or moments, preferably in conjunction with the spectral information described above.