The invention relates to a method and apparatus for identifying a document, typically a document of value such as a banknote, travellers cheque, postal order and the like.
A variety of security document handling equipment has been developed over many years. Typical examples are sorters, counters, validators, dispensers, acceptors and recirculators. Often this equipment needs to identify the documents (e.g. banknote denomination) and this has often been achieved by detecting the size of banknotes (where different denominations have different sizes) and by detecting visible light patterns on the documents for comparison with predetermined references, as in U.S. Pat. No. 4,542,829.
In addition, checks are also made that the documents are genuine and this is commonly achieved by monitoring the UV and IR characteristics of the documents, typically their reflective and/or transmissive response to such irradiation. Examples are described in U.S. Pat. No. 4,127,328, EP-A-0083062, EP-A-0679279, U.S. Pat. No. 4,296,326 and EP-A-0807904.
In large scale document handling equipment, sophisticated detectors can be incorporated for determining identity and authenticity as well as other properties such as degree of soil and the like. Recently, a number of more compact banknote counters have been developed which are able to determine denomination and authenticity and which transport the banknotes either to a single output hopper or to a limited number of output hoppers, for example just two or three. Examples include the De La Rue 2700 and 2800 machines.
There is a need to reduce the size and complexity of this equipment.
In accordance with a first aspect of the present invention, a method of identifying a document comprises exposing the document to infrared radiation; detecting infrared radiation reflected from or transmitted through a plurality of regions of the document to generate at least one test pattern; determining if the or each test pattern satisfies a predetermined relationship with a predetermined pattern or patterns corresponding to a known document; and, if the predetermined relationship is satisfied, identifying the document as being the same as the known document.
In accordance with a second aspect of the present invention, document handling apparatus comprises an infrared inspection station; a transport system for transporting documents past the inspection station, the inspection station comprising an infrared radiation emitter and an infrared radiation receiver for detecting infrared radiation reflected from or transmitted through a document; and a control system coupled to the transport system and the infrared inspection station to generate at least one test pattern from the infrared radiation reflected from or transmitted through a plurality of regions of the document, to determine if the or each test pattern satisfies a predetermined relationship with the predetermined pattern or patterns corresponding to a known document, and, if the relationship is satisfied, to identify the document as being the same as the known document, and thereafter to control the transport system accordingly.
In this new approach, we have realised that it is possible with certain documents such as banknotes, for example US and Spanish currency, to determine identification by reference to reflected or transmitted infra-red radiation properties of the documents. In this way, it is possible not only to determine identification but also authenticity using the same infra-red response or at least the same infra-red inspection station and thus reduce the size and complexity of the apparatus. Typically the same information will be used for both identification and authenticity but in some cases i.r. reflection could be used for identification and i.r. transmission for authenticity or vice versa, or i.r. information from different parts of the document could be used for identification and authenticity respectively.
Although in most cases, the “identity” of the document refers to its denomination or value in the case of banknotes, it can include also or instead orientation or issue.
In addition, the invention enables a new form of non-contact detection to be introduced into the document counting product environment that provides enhanced authentication that was previously only found in the much higher cost document sorting arena. The non-contact nature of the detector provides the advantage that document guiding constraints are minimized and the range of documents that can be processed is maximized.
Although a primary advantage of the invention is that the infra-red response of the document can be used to determine identification, the method could be used in conjunction with a conventional identification detection system such as a visible pattern recognition system to produce additional confirmation of the identity.
The regions which are inspected may be arranged in an irregular or regular array and could be on one or both sides of the document. In the preferred approach, the whole of at least one side of a document is inspected.
The intensity information obtained can be processed in any conventional way. For example, the pattern may be compared using conventional comparison algorithms with one or a number of predetermined patterns corresponding to different identities, issues and/or orientations of documents. Alternatively, the test pattern could be applied to a previously generated neural network which has been trained with the range of genuine documents which are to be identified.
The method can be implemented in a variety of document handling apparatus but is particularly suited for simple document counters having one or a limited number of output locations.
In one example, the infrared inspection station comprises two sets of infrared emitters and detectors arranged on opposite sides of the transport path so as to view opposite sides of the documents. This enables a more accurate determination of identity to be determined since two patterns will be generated from one document. Conveniently, the arrays are offset from one another in the transport direction so as to minimize interference between the two. This also enables each array to be arranged opposite a black reference surface.
Some examples of methods and apparatus according to the invention will now be described with reference to the accompanying drawings, in which:
A pair of stripper wheels 15 are non-rotatably mounted on a drive shaft 16 which is rotatably mounted in the chassis assembly. Each stripper wheel 15 has an insert 17 of rubber in its peripheral surface. Shaft 16 is driven clockwise by a motor 200 (
Transversely in alignment with, and driven from the circumferential peripheral surface of the stripper wheels 15, are pressure rollers 30 which are rotatably mounted on shafts 31 spring-biased towards the stripper wheels 15. Downstream of the wheels 15 is a pair of transport rollers 19 non-rotatably mounted on a shaft 20 rotatably mounted in the chassis assembly. Each roller 19 has a cylindrical form with a constant radius along its axis. Shaft 20 is driven clockwise from a second motor (not shown) to transport the note in the transport arrangement, in conjunction with pairs of pinch rollers 21,23 into stacking wheels 27 and hence output hopper 105. Pinch rollers 21, rotatably mounted on shafts 22 spring based towards the transport rollers 19, transversely align with rollers 19 and are driven by the peripheral surface of the rollers 19. The rollers 23, rotatably mounted on shafts 24 are in alignment with the transport rollers 19, and are essentially caused to rotate by the note passing between the adjacent peripheral surfaces of the rollers 19 and 23.
Situated between the pressure rollers 30 and pinch rollers 21 are separator roller pair 25, non-rotatably mounted on shaft 26 adjustably fixed to a top moulding assembly 32, having a circumferential peripheral surface which is nominally in alignment with the peripheral circumferential surface of, but transversely separated from, the stripper wheels 15.
Also forming part of the top moulding assembly 32, is a curved guide surface 8 extending partly around the circumference of the rollers 15, 19 which, when the top moulding is lifted allows the operator access to the note feed and transport path so that a note jam can be cleared. A surface 37 provides note guiding from the end of the curved guide surface 8 to the conventional stacking wheels 27.
The drive shaft 16 is continuously driven, and this, via a belt and pulley arrangement from shaft 16, causes the auxiliary drive shaft 7 rotating the feed wheel 5 also to be driven. Drive shaft 20, rotating the transport rollers 19, is driven by the other drive motor. A further pulley and belt arrangement (not shown) between shaft 20 and shaft 28, on which the stacking wheels 27 are non-rotatably mounted, provides the drive to the stacking wheels 27.
The guide plate 8 extends as a continuation of the base of the hopper 2 towards the nips formed between the transport rollers 19 and the rollers 23.
An infra-red head 50 is mounted downstream of the rollers 21 and includes a linear array of infra-red emitting diodes 51 (
The infra-red head 50 is connected to a microprocessor 65 which is also connected to the memory 60. This is described in more detail in WO-A-00/26861 incorporated herein by reference and so will not be described in detail. The microprocessor 65 is programmed to identify the denomination of the banknote and also its authenticity. In one example, the denomination and authenticity are determined separately. For example, certain regions of the banknote will be reviewed for the purposes of denomination determination while other regions will be reviewed for purposes of authenticity. However, in other applications, particularly if the whole banknote is considered, then a single process can be used to establish both denomination and authenticity.
As far as denomination is concerned, the processor 65 compares all or part of the test pattern stored in the memory 60 with a plurality of reference or prestored patterns in a memory 70. These prestored patterns will have been generated in any conventional manner from a set of genuine banknotes.
Thus, as set out in
The pattern matching technique used in step 85 can be of any conventional type, a preferred approach being described in WO-A-00/26861. Other examples are described in U.S. Pat. No. 4,179,685 and EP-A-0883094.
As mentioned above, the processor 65 could carry out a separate authenticity determination by looking at a particular region of the banknote to see whether the infra-red reflectance satisfies a predetermined condition or alternatively this could be inherent in the pattern recognition process carried out to determine denomination. In either event, if the processor 65 is satisfied that the banknote is authentic and its denomination has been identified it will then control the subsequent processing and handling of the banknote. In this example, the banknote will be allowed to continue on to the output hopper 105 and further banknotes will be fed from the input hopper 2.
If the processor 65 determines that the banknote is not authentic or cannot be identified then the motor 200 is stopped to prevent further banknotes from being fed to the output hopper and a suitable error message will be displayed allowing the operator to remove the suspect banknote.
In the example just described, a single IR head 50 was provided.
In the
The apparatus shown in
Alternatively, the detection systems described with reference to
In the case of a transmissive system, the detector(s) would be located on the opposite side of the transport from the corresponding emitter(s) in a similar way to the arrangement shown in WO-A-00/26861.
The counter 100 shown in
As can be seen, the bank notes are stacked on the base 402 and are urged forward against the front wall 426. A small gap 427 is provided at the base of the front wall, through which individual bank notes and separators can be nudged.
The pattern recognition system 414A,414B operates on the detected image data in an exactly similar way to the pattern recognition system of the previous example, for example as described in WO-A-00/26861. In this case, however, instead of stopping the transport when an unsatisfactory condition is determined such as a double note feed or the like, the diverter 420 is operated so that the unacceptable notes are fed to the reject bin 43.
In another alternative (not shown), in any of these examples bi-colour LEDs or sets of alternately activatable red and i.r. LEDs could be used to obtain visible and i.r. pattern data for subsequent processing by suitably switching activation of the LEDs as the note is scanned.
In all the examples, notes are typically processed at transport speeds in excess of 800 notes per minute, usually in excess of 1200 notes per minute.
Number | Date | Country | Kind |
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0105612.6 | Mar 2001 | GB | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/GB02/00836 | 2/26/2002 | WO | 00 | 9/22/2003 |
Publishing Document | Publishing Date | Country | Kind |
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WO02/071348 | 9/12/2002 | WO | A |
Number | Name | Date | Kind |
---|---|---|---|
4127328 | Gorgone et al. | Nov 1978 | A |
4542829 | Emery et al. | Sep 1985 | A |
5875259 | Mennie et al. | Feb 1999 | A |
6980684 | Munro et al. | Dec 2005 | B1 |
Number | Date | Country | |
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20040218800 A1 | Nov 2004 | US |