WO1999009528A1 - Security element structure for documents, devices for controlling documents comprising such security elements, and method for using said security elements and devices - Google Patents

Abstract

The invention concerns the security element structure for documents, devices for controlling documents comprising such security elements, and a method for using said security elements and devices as per the patent application DE 197 34 855.6. The invention aims at completing the security element structure for documents, and at proposing devices for controlling such security elements, an a novel method for using these security elements and devices, making it very difficult, if not impossible, for forgers to discover how the methods and devices work, as far as the security elements are concerned, and subsequently produce forged documents so identical to the original documents as to make them undetectable by the control devices. The security element structure for documents to be controlled corresponds to the new design which is not based primarily on visual observation but on control methods. Said design referred to below as functional design, results from the combination of electrically conducting and insulating structures of identical or different sizes, in identical or different planes, with identical or different conductivity, and it is materialised by metal-coated structures and/or writing or printing electrically conductive inks.

Description

Construction of security elements for documents and devices for checking documents with such security elements as well as methods for using these security elements and devices

The invention relates to the construction of security elements for documents and devices for checking documents with such security elements as well as methods for using these security elements and devices according to patent application DE 197 34 855.6.

So far, documents with diffraction-optically effective security elements have been checked using complex optical testing technology. It is not possible, for example, to test documents with security elements with optical diffraction effects or with so-called OVDs (optical variable devices) within a document processing machine, since this works at high speeds.

DE 27 47 156 describes a method and a test device for checking the authenticity of holographically secured identity cards. The OVD is reproduced and then subjected to a visual inspection. This procedure is not suitable for quick, efficient, person-independent testing. EP 0 042 946 describes a device for generating scanning patterns which are checked using a laser, mirror and lens system and a photodetector. The economic effort is very high in this case too. It would increase even further if the test material was to be checked unsorted. To avoid pre-sorting, would be a multiple arrangement of the authenticity check system or a multiple check necessary.

EP 0 092 691 AI describes a device for detecting security strips in

Banknotes described. The material-specific absorption bands of a plastic security strip are measured with the help of two transmitted light measuring channels in the infrared range at wavelengths of about 5 mm. An authenticity or quality check of diffractive optical security elements that reflect metallic, such as

for example reflex holograms or Kinegra me, is not described in said EP, would not be possible with the named device. From GB 21 60 644 A it is known to use a line scan camera to check the reflected light of banknotes, and from CH-PS 652 355 it is known to check cards with a special layer structure using the reflected or transmitted light method. In both cases it is a test in which the image information obtained is compared with the originals. The reflections and signs of use that occur in both methods are problematic and therefore of great disadvantage.

An automatic authenticity check of hologram information is described in DE-OS 38 11 905. The arrangement described in DE-OS provides for the transmitted light hologram test to arrange the transmitter and receiver directly opposite one another in order to be able to analyze the hologram information. This opposite arrangement of transmitter and receiver has an oversteering disadvantageous in terms of measurement technology and possibly even damage to the recording elements due to direct incidence of light in the spaces between the successive banknotes. When checking used banknotes, existing creases make testing practically impossible due to accidental reflections. According to the known methods described above, an exact positioning of the

Test objects are required and all devices are not suitable for high-speed ones

Processing machines.

In DE 196 04 856 AI it is proposed to carry out the condition, quality or passport control of optical security features in the form of metallic reflective layers such as kinegrams, holograms and the like on securities, in particular banknotes, in such a way that a metallic reflective security feature of the security in a manner known per se in transmitted light by means of at least one electronic camera, preferably a CCD line scan camera, and the actual values determined in this way are compared with target values by means of image evaluation methods known per se in order to detect banknotes with defective security features mark or discard used notes in a sorting system. The device, as described in DE 196 04 856 AI, is characterized by a transport device known per se for moving the securities in the area of the electronic camera, an infrared radiation source on the side of the security to be checked facing away from the camera, and that the optical axis of the camera encloses an angle deviating from 180 ° with the optical axis of the lighting device and the transport device is preferably formed by transport belts which are spaced apart from one another transversely to the transport direction. This device or method also has the disadvantage that, in particular, used banknotes with creases or banknotes which have a damaged or contaminated kinegram film on their surface are not recognized as real banknotes. In addition, the described method and the associated device are automated, but are not suitable for the high-speed banknote machines in circulation with a throughput of 1,200 pieces per minute. Diffraction-optically effective security features or OVD's on securities such as the German 100 and 200 DM banknotes are currently being checked manually or visually for damage, register accuracy, exact margins, etc. The check is carried out visually both in the production of banknotes and in the sorting out of banknotes flowing back from the circulation, if necessary. This procedure is time consuming and costly. In addition, the test is inaccurate because, for example, in the case of security elements having an optical diffraction effect, the demetallized zones have been produced, for example by means of chemical etching processes, according to customary practice to date. As is known, these processes do not allow an exact course of desired structures. As a rule, "frayed" edge runs arise.

DE 195 42 995 AI describes, among other things, a method for checking the authenticity of a data carrier by comparing the various data available. According to this patent, the following options are available:

Comparison of the standard image of the hologram with that of the storage unit, comparison of the hologram data of the hologram with the data in a defined area of the data carrier and / or that of a storage unit,

Comparison of the hologram data with the data which are available via an input unit,

- Comparison of the individual image of the hologram with data of the input unit of the storage unit and / or the data of the defined area.

This process is also time-consuming and costly. The test is carried out optically by comparison via image recognition with a reader and is therefore for

high-speed processing or testing machines are not suitable. As already stated in the patent application DE 197 34 855.6, diffraction-optically effective security elements or OVDs are only used to achieve optical effects and can only be checked using optical test methods or by visual inspection. Other test methods, in particular those for use in high-speed processing machines, are not known.

The known features, test zones and structures to be tested as well as the test methods and devices for the authenticity test of objects, securities, in particular banknotes, have the main disadvantage, which lies in their popularity. In fact, in a familiarity that enables the counterfeiter to draw conclusions from the knowledge of the test methods and devices and their functioning regarding the characteristics to be tested, the test zones and structures. This leads to a completely new task for the inspection of objects, securities, in particular banknotes, the solution of which must be reflected in a new procedure for the use of inspection features, inspection procedures and devices in order to prevent information codes from being easily found and copied.

The object of the invention is to eliminate the disadvantages of the prior art and in particular to complete the structure of security elements for documents with further security elements and to propose devices for testing such security elements and a new method of using security elements and devices which are essential to the counterfeiter complicate, if not make impossible, of the functioning of test methods and devices towards them close security elements in order to produce false certificates which are so similar to the originals that they cannot be detected by inspection devices. It is also an object of the invention to propose safety elements and features or OVDs which have an optical diffraction effect and which can be checked quickly, independently of the person and with little effort and precisely. The associated devices for testing security features are to be used both in high-speed document processing machines and in manual testing devices. Furthermore, it is an object of the invention to design several of the devices according to the invention so that they check a defined number of several security elements or features present on a document, the number of security elements to be checked differing between the devices. This task aims to achieve different test criteria according to the possible cost and the testable security elements.

The task is solved by the following description of the invention.

The construction of security elements for documents to be checked provides for a new design that is not primarily focused on visual inspection, but rather on test procedures. This design - hereinafter referred to as a functional design - is the combination of electrically conductive and insulating structures of the same or different sizes, in the same or different levels to one another, with the same or different conductivities, and is produced from metallized structures and / or

conductive inks or inks. In its diversity and different composition, the functional design is encoded in all distinguishable security elements and is therefore encrypted and can be checked. The functional one According to the invention, design can be a diffractive optical security element or consist of electrically conductive paints or inks. If it is designed as a diffractive optically effective security element, it can match the optically, ie visually perceptible design and even support it in its optical design.

Structures of metallizations and electrically conductive colors or inks in the form of lines, dots and figures which can be checked by means of capacitive coupling are referred to as security elements. Such security elements are arranged on documents individually or in combination. A security feature consists of at least one security element, preferably an accumulation of security elements of the same or different arrangement, size, color and / or conductivity.

Using known manufacturing technologies, diffraction-optically effective security elements are produced according to the invention from metallized structures instead of previous demetallization of individual structures. In order to produce the security elements to be tested with a high quality, according to the invention metallized security elements are produced with a very close approximation to the desired metallized structure and steep edges to neighboring insulating structures. The steepness of these edges means that microstructures can be produced and checked. As already explained above, demetallized zones are, for example, in the case of safety elements which have an optical diffraction effect according to customary practice to date

generated by chemical etching. As is known, these processes do not allow any steepness of the edges or an exact course of the desired structures. It As a rule, "frayed" edge runs arise. These edge runs do not allow the demetallization zones with widths in the tenths of a millimeter range to be used as a functional design. In order to achieve exact edge runs for a functional design, a different manufacturing technology must be used Metallization with adjacent non-metallized zones is carried out in known high-vacuum vapor deposition systems. For counterfeiters, this means an increased cost in the production of falsifications. , arc-shaped and / or circular security element with a line width <5 mm. These security elements simultaneously represent a coding of information that can be obtained by means of the invention

Devices are recognized and evaluated.

The device for testing described security elements according to the invention has a capacitive scanner. This scanner consists of a plurality of transmitting electrodes lying next to one another in one or more rows and a receiving electrode lying parallel to this series. This scanner with small electrode areas has the advantage over sensors with large-area electrodes that there is less capacitive coupling between the individual electrodes. The scanner is arranged in a document processing machine in such a way that the optical or mechanical sensors present in conventional document processing mechanisms activate the test device according to the invention. To reduce detection and measurement errors, a sensor carrier is preferably used, which receives all sensors for testing. The distances between the sensors are minimized. This minimization of the distances between the sensors is to reduce the change in position of the test Documents required because the position of the documents changes during the document run due to the document condition, the degree of wear of the machine and environmental conditions, in particular temperature and humidity. The document distance from one another changes due to unfavorable document feeding. Skewed document flow can also result from wear and tear on transport rollers and bearings, which also means that a document that has just been pulled in is twisted during transport. This undesired change in position has the consequence that the defined time sequence is disturbed and false rejections occur. The smaller the security elements, the more problematic it is to detect them. The device according to the invention has a pressure device which represents a very low resistance for the document. This pressure device guides the document parallel to the transmitting and receiving electrodes or presses the document to be checked preferably onto the scanner. Furthermore, the axes of the transport rollers are connected to earth by means of sliding contacts. These additional shields and the pressure device guarantee repeatable test requirements with an even document spacing or contact and the functionality of the sensor is significantly improved. The control of the individual transmitter electrodes with electrical energy is carried out with a time delay by means of control electronics with a switching frequency in the kHz range and beyond. The main components of the control electronics in addition to the power supply are a multiplexer, an oscillator for providing the energy for the transmitting electrodes and an oscillator for controlling the multiplexer. In the case of electrical conductivity, the energy of the respective controlled transmission electrode is capacitively coupled between this transmission and the reception electrode. The signal curve at the receiving electrode is converted into a corresponding signal image. The The signal pattern depends on the metallized structure of the diffractive optical security element. An evaluation electronics following the receiving electrode compares the signal image of the test document with corresponding reference signals. The evaluation electronics essentially consist of a power supply, an amplifier, a demodulator, a comparator, a microprocessor with memory and filters to suppress external and interference signals.

In addition to the software for the microprocessor, reference signal images are stored in the memory and, depending on the security elements to be tested, are compared with the scanned signal image of the test document. Since the scanner extends across the entire width of the document, each electrically conductive security element is detected using the device according to the invention. The comparison with the reference signal images provides a classifying signal for further processing. Accordingly, for example, a document recognized as a false certificate could be sorted out by stopping the checking device or redirecting the document transport route. In order to reduce interference, the sensor carrier is compactly connected to a circuit board that carries the control and evaluation electronics.

In a modification of the electrode arrangement, it is within the scope of the invention to arrange an elongated transmitting electrode parallel to a row of a plurality of adjacent receiving electrodes. In this case, the received signals are processed using a multiplexer. The other evaluation electronics correspond to those already described.

A further embodiment of the transmit and receive electrodes is characterized in that a plurality of transmit and receive electrodes side by side and / or in series are arranged. Both the control and the reception of the signals are processed using the multiplex or demultiplex method.

For use in handheld devices, these contain corresponding devices for transporting the document or the scanner, the function of which is similar to that of the transport devices in copiers, optical image feed scanners or fax machines. In a modification to this, a device is provided which defines the position of the capacitive scanner of the inventive test device in relation to the document by means of stop elements.

For the targeted testing of a defined number of security elements of a document, the device has a different number of transmitting or receiving electrodes lying next to one another. The greater the resolution achieved in this way, the more security elements and encodings with an increased level of difficulty in counterfeiting can be checked. This allows simple handheld devices, e.g. simple, easy to handle and inexpensive to manufacture for everyday use, where the presence of security features, e.g. a simple security thread can be checked. Devices with a higher resolution allow the testing of additional security elements, but without being able to recognize all the security elements. This is implemented using simple microprocessor software that is only sensitive to certain security features and is not public. A higher resolution with appropriately designed software for the microcontroller allows all security features to be checked. This high test effort is e.g. used by the manufacturers of such security features and by users with a very high security standard in order to obtain the best possible test results. This also allows different

Detect conductivity reliably. In addition to the overall system of use of the described security elements and devices for checking documents, the invention also includes carrying out image recognition and status checking of the documents. Image detection by means of the coding is possible by means of the electrically conductive security elements, namely an independent coding or as a supporting aid for sorting purposes, a coding for value level determination and a coding for authenticity determination. With an independent coding, no further security element is present and the electrically conductive security element must be clearly identifiable, e.g. For example, the position on the document to minimize the incorrect rejection rate. In the case of a coding which supports as an aid, further features are available, the coding then serves as a reference means in the event that an incorrect rejection has been detected. A condition check is carried out with the aid of the test device according to the invention in the form that the conductivity of a security element allows conclusions to be drawn about the condition of the document, because experience has shown that a heavily used document also leads to wear on the electrically conductive structures and thus changes in the electrical conductivity. The individual degrees of wear are classified using software. In this way, defined documents with a certain degree of wear can be sorted out. This degree of wear is expressed, for. B. by a partially damaged OVD, a torn document and a damaged security element or an excessively wrinkled document, which has resulted in a break within a security element. This results in a wide range of possible combinations between authenticity testing, image recognition and status control. In addition to the optical design of security features on a document to be checked - as described in more detail above - the security elements according to the invention are provided with codes which are shown in a mathematical relationship to one another - for example, as a sum formation - result in a main code, which in turn determines the authenticity, the condition or the type of a specific document with a signal or code from the synchronous authenticity check of a metallic security thread and / or an equally synchronous check of an OVD.

In addition to the claims, the features of the invention also emerge from the description and the drawings, the individual features representing advantageous, protectable designs, individually or in groups in the form of sub-combinations, for which protection is claimed here. Embodiments of the invention are shown in the drawings and are explained in more detail below.

The drawings show:

Fig. 1 shows a schematic representation of a document with määnderförrnigem metallized security feature, Fig. 2, 3 schematic representation of documents with strip ^'RMIG metallized security elements; FIG. 4 schematic representation of a document with gitterfδrmig metallised security feature, Fig. 5 shows a schematic representation of a document with several security features ,

6 block diagram of a test device,

7 - 9 schematic representation of different types of scanners, FIG. 10 schematic representation of the scanner and a document to be checked in a side view, 11 shows a schematic section through metallized security elements, FIG. 12 shows a voltage-time diagram of the evaluation signal for FIG. 11, FIGS. 13-15 show schematic representations of scanners and a structured security feature.

The examples shown in FIGS. 1 to 5 each show documents with security elements according to the invention, the capacitive scanner of the device according to the invention also being shown schematically. 1 shows the schematic structure of a security feature 1 with metallized layers 2. The metallized layers 2 are separated by an insulating zone 3. The top view of the insulating zone 3 is shaped like a meander. The width of the insulating zone 3 in the form of a meander is larger than the smallest distance between two electrodes. The capacitive scanner 4 consists of a plurality of transmitter electrodes 5 lying next to one another and a reception electrode 6 lying parallel to this series.

Fig. 2 shows the schematic structure of a security feature 1, wherein the alternately RMIG metallized zones 7 and insulating strip-shaped zones 8 strip ^'parallel to one another. The zones 7, 8 which are strip-shaped in plan view run parallel or perpendicular to the document transport direction. The latter case is shown in Fig. 3. The distance between two zones of the same electrical conductivity is between 0.2 mm and 1.0 mm. The widths of the zones with the same electrical conductivity vary. Different conductive zones with different widths are also possible. A combination of the features from FIGS. 2 and 3 is shown in FIG. 4. Parallel to the document transport direction, striped metallized zones 7 and insulating striped zones 8 are alternately arranged. The metallized zones 7 are interrupted by a strip-shaped insulating zone 9 running perpendicularly thereto. 5 shows a document with several security features. The targeted combination results in further coding. This increases test security. 6 to 9 illustrate the block diagram and various configurations of the capacitive scanner 4. FIG. 6 shows the block diagram of the test device according to the invention, consisting of control electronics, a capacitive scanner 4 and evaluation electronics. In addition to the power supply, the control electronics essentially contain a demultiplexer 10, an oscillator 11 for providing the energy for the transmitting electrodes and an oscillator 12 for controlling the demultiplexer. The evaluation electronics mainly consist of a power supply, an amplifier 13, a demodulator 14, a comparator 15, a microprocessor 16 with memory and filters for suppressing external and interference signals. The transmitter and receiver electrodes are cast in a sensor carrier. These form a capacitive scanner 4 over the entire width of the document feeder. The strip-shaped receiving electrode runs transversely to the direction of the document feeder. The transmitting electrodes are arranged parallel to the receiving electrode. The distance between a transmitting electrode and the receiving electrode is determined by the electrically conductive security elements typical of the document. By lining up a plurality of transmitting electrodes, it is possible to simultaneously detect several electrically conductive features in the longitudinal axis of the capacitive scanner 4. The one with this The arrangement achievable resolution depends on the number of transmitting electrodes used. In this embodiment, the resolution is at a scannable point / mm in both the longitudinal and transverse directions. The minimum distance between adjacent transmission electrodes is limited by the interfering capacitive coupling. In order to prevent this and to reduce interfering influences from adjacent transmission electrodes, the transmission electrodes are controlled in succession by a multiplexer 10. Due to the arrangement of the transmitting electrodes over the entire document feed width, the documents are checked in a position-neutral manner. This means that there is no pre-sorting of several documents in one document processing machine. FIG. 7 shows the schematic representation of the scanner 4 with a multiplicity of transmitting electrodes 5 and a receiving electrode 6. The control and evaluation is carried out according to the block diagram shown in FIG. 6.

FIG. 8 shows the schematic representation of an embodiment of the capacitive scanner with a transmitting electrode 17 and a plurality of receiving electrodes 18. In a modification of the block diagram according to FIG. 6, the transmitting electrode 17 is controlled by means of an oscillator. The signals of the receiving electrodes 18 are processed by means of multiplexers. The further evaluation electronics, consisting of a power supply, an amplifier, a demodulator, a comparator, a microprocessor with memory and filters for suppressing external and interference signals, is similar to the block diagram according to FIG. 6. FIG. 9 shows the schematic representation of a further embodiment of the capacitive scanner with a plurality of transmitting electrodes 19 and a plurality of receiving electrodes 20. These are alternately arranged in a row. Accordingly, both the drive signals of the transmission electrodes 19 and Processing signals of the receiving electrodes 20 processed by means of multiplex or demultiplexing.

10 shows a schematic illustration of the capacitive scanner 4 and a document to be checked in a side view. The security feature 1 includes metallized lines 21 and an electrically insulating carrier film 22.

FIG. 11 shows a schematic section through a security feature with a carrier layer 23 and a partially metallized layer 24. The partially metallized layer 24 contains a plurality of insulating segments 25. The partially metallized layer 26 has a different electrical conductivity than the partially metallized layer 24. In Fig. 12 shows the associated evaluation signal in a voltage-time diagram.

13 to 15 show schematic representations of scanners 33, 34, 35 and a structured security feature 36. The structure of the security feature 36 consists of an annularly metallized security element 37, a strip-like metallized security element 38 and two rectangularly metallized security elements 39, 40 Test security is achieved through the noticeably high edge steepness of the metallizations, as this greatly increases the amount of forgery. Simple hand-held devices include a scanner 33 according to FIG. 13. The resolution is so low that only the strip-shaped security element 38 can be detected. Handheld devices of this type are suitable for everyday use because they are simple, easy to handle and inexpensive to produce. 14 have a scanner 34 and, in addition to checking a strip-shaped security element 38, allow the checking of additional security elements, in this case an annular security element 37. The rectangular security elements 39, 40 are not checked. This is implemented using simple microprocessor software that only works with certain security elements is sensitized. The rectangular security elements 39, 40 are not present in the memory as reference signal images.

A higher resolution with appropriately designed software for the microcontroller shows

Fig. 15. This allows all security features to be checked, i. H. also the rectangular security elements 39, 40. To maintain the brilliance of the optically effective

The microstructures become security elements through targeted metallization

manufactured. This creates steep edges to non-metallized structures.

To fulfill the task on which the invention is based, namely a new one

To propose methods of using security elements and test devices in order to make the operation known

To counter test methods and devices, subsequent use of

Security elements explained using the corresponding method and incorporating devices according to the invention.

For the broad application of the invention, it is necessary to define groups of inspectors who receive specific knowledge of an inspection system in a targeted manner and, in particular, use authenticity inspection but also image recognition and condition inspection by means of prescribed inspection technology.

The use of the test system is to be explained on the basis of groups A, B, C.

Group A:

As is known, the state banks make publications on active security features of banknotes, so that the user can carry out a check himself following instructions. These publications relate to test methods which are carried out without and test methods which are carried out with auxiliary means become. The scanner sensor is built into a handheld device. This handheld device and special software are used to test the electrical conductivity of certain

Security elements.

The software is modified in such a way that when the banknote is pulled through optical sensors, the scanner is activated and the throughput length is then measured. The electrical conductivity of a security element must be present in a fixed value. The end of the banknote is determined by means of optical sensors and the scanner sensor is deactivated. The position of an electrically conductive security element on the test object can thus be determined. The data are compared with the stored data and evaluated using a controller.

Group B:

Group B has machines for processing banknotes. These machines are equipped with special sensors to detect different features. These machines are currently equipped with sensors for the optical range and / or the detection of magnetic properties and / or testing by means of a capacitive sensor for measuring the length of passage. With these capacitive sensors, the presence of electrically conductive features larger than 6 mm can be detected. They do not permit the detection of several electrically conductive security elements in a pass width. In addition, the detection of different electrical conductivity in the

Security features not possible. Structures within a security feature can also not be detected. However, these tests are possible by means of the scanner sensor described, so that group B can carry out a higher-quality test. The software for group B is designed such that the scanner sensor is activated by means of optical sensors and then the ring-shaped metalized security feature 37 and the striped metalized security feature 38 are recognized. The value of the conductivity is fixed. Deviations above or below 30% are rejected.

Group C:

The software is designed in such a way that all security elements are recognized. By means of optical

Sensors, the scanner sensor is activated. The passage length and the passage width of the security feature 36, the ring-shaped metallized security element 37, the strip-shaped security element 38 and the rectangular security elements 39, 40 are recognized. The electrical conductivity is specified and deviations greater and less than 30% are rejected. The entire test system can be varied, particularly for use in groups B and C, and its tasks can be changed nationally, particularly when testing the euro. Since the security feature to be checked is the same for all countries, for example in the case of the euro, both the test procedure and the test devices can be modified nationally depending on the focal points and changed one after the other. The application of the security elements and test devices, as described above, is used as follows: Using the coded, targeted metallizations, an image can be detected. This image recognition can be used for different purposes, in particular sorting purposes, determination of the value level or authenticity. Another advantage of the test method is the condition control. The electrical conductivity measurement leaves Conclusions about the condition of the banknote paper. Very badly worn paper will greatly reduce electrical conductivity.

In the present invention, the structure of security elements and a device for testing such elements was explained using specific exemplary embodiments. However, it should be noted that the present invention is not restricted to the details of the description in the exemplary embodiments, since changes and modifications are claimed within the scope of the patent claims. The targeted combination of optically diffractive security elements with other electrically conductive features results in a further coding. At the same time, other electrically conductive test features, such as. B. classify an electrically conductive security thread using the test device according to the invention.

Claims

claims

1. Structure of diffraction-optically effective security elements in documents according to patent application DE 197 34 855.6, characterized by targeted electrical coding of information by means of beams, gratings, arcs and / or circular electrically conductive structures with steep edges to neighboring ones

non-metallized structures, the line width of the smallest testable electrically conductive structure being less than or equal to 5 mm.

2. Structure of security elements according to claim 1, characterized by a targeted electrical coding of information by means of bars, gratings, arches and / or circular metallized structures with steep edges to adjacent non-metallized structures, the line width of the smallest testable metallized structures being smaller or is 5 mm.

3. Structure of security elements according to one or more of the preceding claims, characterized in that different metallized security elements have different conductivities.

4. Structure of security elements according to one or more of the preceding claims, characterized in that at least two structures within a security feature have different metallization thicknesses.

5. Structure of security elements according to one or more of the preceding claims, characterized in that the width of a metallized structure with constant electrical conductivity corresponds to the width of at least two electrodes of a test device.

6. Structure of security elements according to one or more of the preceding claims, characterized in that the distance between two metallized structures of the same and / or different electrical conductivity is at least 0.1 mm.

7. Apparatus for checking documents with diffraction-optically effective security elements according to patent application DE 197 34 855.6, characterized in that a capacitive scanner (4, 33-35), metallized security elements (39, 40) within metallized security elements (37) are arranged by means of one in a row in one or more

Checks rows of electrodes lying next to one another and evaluates them via control and evaluation electronics arranged in the scanner (4, 33-35) to compare the signal curve of the document to be checked with corresponding reference signal curves.

8. The device according to claim 7, characterized in that at least two adjacent electrodes are arranged electrically connected.

9. The device according to claim 7 or 8, characterized in that the control electronics from a power supply, a multiplexer (10), an oscillator (11) for providing the energy for the transmitting electrodes (5) and an oscillator (12) for controlling the multiplexer (10) exists.

10. The device according to one or more of claims 7 to 9, characterized in that the evaluation electronics from a power supply, an amplifier (13), a demodulator (14), a comparator (15), a microprocessor (16) with memory and filters for the suppression of external and interference signals.

11. The device according to one or more of claims 7 to 10, characterized in that the smallest distance between two transmitting electrodes (5) is less than 0.5 mm.

12. The device according to one or more of claims 7 to 11, characterized in that the distance between a transmitting electrode (5) and the receiving electrode (6) is at least 0.5 mm.

13. The device according to one or more of the preceding claims 7 to 12, characterized in that the device has a pressure device which leads the document to be checked parallel to the transmitting and receiving electrodes,

preferably presses on the scanner.

14. The device according to one or more of the preceding claims 7 to 13,

characterized in that the axes of document transport rollers by means of

Sliding contacts are connected to ground.

15. The device according to one or more of claims 7 to 14, characterized

characterized in that the device in high-speed document processing

maschmen is arranged.

16. The device according to one or more of claims 7 to 15, characterized

characterized in that the device is arranged in hand-held devices.

17. The method according to patent application DE 197 34 855.6 for the application of

Diffraction-optical security elements in documents with a structure according to

one or more of claims 1 to 6 and application of a device

according to one or more of claims 7 to 16, characterized in that

metallized test elements in the form of metallized layers (2, 24, 26),

metallized zones (7), metallized lines (21) or metallized

Security elements (37-40) in size, shape, number, color and spacing

are arranged one below the other on documents to be checked,

- That with a scanner designed as a handheld device (33) at least one of the

metallized test elements from a group of people A,

- That with one of the equipped with special software and in a high-speed

Machine installed scanner (34) at least two of the metallized

Test elements from a smaller defined group of people B, - That with a equipped with a highly specialized software and in a high-speed processing machine (35) at least three of the metallized test elements are checked by a very small defined group of people C and

- That the metallized test elements represent codes that can be perceived by the group of people A visually, by the group of people B visually and via decoding using software and by the group of people C mainly via groups A and B inaccessible decoding using software

are.