JPH11509343A - Method and apparatus for collating confidential documents - Google Patents

Abstract

(57) [Summary] The present invention relates to a method and an apparatus for collating confidential documents. According to this process using known capacitive coupling, the electrical signal is transmitted by the transmitting antenna to the receiving antenna via the conductivity assurance element and amplified. The amplitude and time characteristics of the electrical signal are evaluated by being converted into a signal response having easily comparable parameters and compared to the current signal response. Selective amplifiers are further coupled to the evaluation electronics to explicitly select the test arrangement. With the evaluation electronics according to the invention, a currency-specific definition is obtained, and for a given currency, the time limit of the test signal amplitude is determined by the controller. This time limit is, for example, different from the duration of the amplitude response of all other money.

Description

The present invention relates to a method and an apparatus for verifying or checking a security document as described in the preamble of claim 1. Many processes, devices, methods and inspection systems are known not only to limit or count money, but also to determine the authenticity of confidential documents, check their validity, and determine their placement in processing equipment. . German Patent 1,223,594 describes a device for capacitive sensing image material in which sensing capacitors consisting of sensor electrodes are arranged on both sides of the path of movement of the image material. This device is not warranted to detect embedded strips, stamped or stuck conductive strips, ribbons or other small pieces. German Patent No. 1,774,290 describes an observation arrangement for automatically evaluating banknote-specific elements in a device for checking the authenticity of banknotes by means of capacitive electrode pairs arranged in a grid-like pattern. I have. This known observation arrangement does not allow an accurate determination of each specific element at the currently required processing speed, and in slower matching processing only the presence of such elements is detected, It is inadequate against currently known counterfeiting using conductive elements in a ticket. In German published specification No. 2,619,457, the magnetic properties of test strips provided in banknotes are measured. German Patent No. 2,834,287 describes checking the authenticity of a ferromagnetic security strip in a printed confidential document by using a magnetic field. These inspection methods are very slow and always require precise positioning of the object or strip to be verified. German Patent No. 2,760,165 describes a technically complex inspection device in which the authenticity of banknotes is determined by observing other inspection parts, in particular differences in thickness and fluorescence properties. Examining only these characteristics no longer corresponds to counterfeiting patterns currently in circulation. Counterfeit confidential documents, including water marks and fluorescent paper or dyes, are no longer recognized as counterfeit by this device. In particular, the read head of the processing device described in German published specifications Nos. 3,236,373 and 3,236,374 is to provide a sensitive document by forming a capacitor and introducing a ferroelectric material between the capacitive electrodes of the read element. Affects the change in the predetermined capacitance value for the above indicia. Even the read head is unsuitable for inspecting high-speed processing devices and the European banknotes currently in circulation. Determining the presence of conductive assurance strips by means of an untuned oscillator and a resonant circuit according to German Patent 2,912,712 is accepted due to the low reputation of reliability and the high technical complexity and complex structure. Absent. U.S. Pat. No. 5,308,992 describes the observation arrangement of optical and capacitive sensors, but requires accurate positioning of the test strip. The use of additional magnetic sensors has been proposed to improve the rate of error-free operation and to distinguish between different test objects (e.g. different currencies), creating more complex and expensive observation configurations doing. Subsequent to resorting the banknotes, the capacitive sensor is only capable of detecting the presence of a conductive security strip. German Patent No. 4,103,832 discloses a test arrangement in which capacitive sensors and / or electro-optical sensors and / or millimeter-wave sensors are arranged to match along a matching path. The subject matter of this disclosure relates specifically to testing the dielectric properties of banknotes. An essential disadvantage of these known inspection methods and arrangements is their high technical complexity for detecting counterfeiting in banknotes that are rapidly fed through secure document processing equipment. And poor reliability. Disadvantages of the known observation arrangement for sensing the capacitive properties are that the sufficiently low capacitive resistance is only in the supplied low frequency range from 10 to 220 kHz and with a small gap between the electrode and the metal strip. It can only be built. Furthermore, in this frequency range, the effect of the dielectric charge is still insignificant, i.e., a material with a relatively high dielectric constant results in an increase in the capacitance and thus a decrease in the capacitive resistance between the antennas. Thus, for example, wet forgery is perceived as genuine. In practice, these arrangements, especially with respect to mechanized authenticity matching, have not been successful to date. European Patent No. 589,195 A2 discloses that a device having an excitation coil and a sensor coil is used to determine the authenticity of a test object by detecting a sensing area provided with a magnetic element having a high permeability with an allocated code. It describes how to derive from a given detection signal and that its authenticity is revealed when the detection signal and the assigned code match. This matching method can be used to some extent only on plastic cards, paper securities and a small number of non-European banknotes with magnets or magnetizable strips. Other matching methods described in European Patent Nos. 204,574 A2, 553,401 A1 and 506,023 A1 for the geometric and / or physical properties of the test object are classified according to the method of comparison. And can be used only with certain types of test objects, which are very complex and unacceptable as a single-action credibility verification method due to the desired high speed. Eliminating the disadvantages of known arrangements and methods by ensuring the inspection of specific test elements, for example various banknotes containing wet or intentionally moistened and / or soiled test objects And is used for money, distinguishes them from each other, has low technical complexity, and is effective to be executed in a retro-fit processing device. It is one of the objects of the present invention to satisfy the rapid throughput in the treatment apparatus. Conductive security wires or ribbons in banknotes or confidential documents (securities) or security elements formed two-dimensionally are used as unique inspection elements. It is a further object to configure an inspection unit that performs a method in which credibility matching is performed prior to classification based on money or the like. Developed a device that inspects confidential documents on assurance elements, including conductive ribbons or fine-wire-like strips, and inspects continuous conductive strips with multiple conductive areas electrically isolated from each other It is yet another object of the present invention to do so. An example of such a confidential document is current U.S. banknotes with security wires that maintain conductive properties isolated from each other. As a modern practice, the process by which such an inspection system recognizes not only high quality counterfeiting, but also genuine confidential documents of low quality, which in fact frequently occurs and which considerably hinders the operation of the processing device. Requires incorporation of equipment. In order to take advantage of the kind of capacitive coupling known per se, the method according to the invention for inspecting confidential documents comprises transmitting and amplifying an electrical signal from a transmitting antenna to a receiving antenna via a conductive element. provide. The conductive element is evaluated after an amplitude response after a predetermined time, converted into a signal pattern with easily comparable parameters and compared with the current signal pattern. In order to carry out the method with these steps described, an inspection device utilizing capacitive coupling requires a security strip or wire or a two-dimensional security element used in a banknote processing device, rather than a counting device. Proposed for banknotes, confidential documents, securities, and the like provided. The sensor array is located in the housing assembly near the optical and / or magnetic sensors and / or the format sensors. The device allows banknotes and / or securities to pass through the inspection device. The sensor arrangement comprises a plurality of antennas and / or electrodes. The vertical length of the surface area of the antenna and / or the electrodes in a direction perpendicular to the feed path, even when acting from a given side of the test object, also indicates that the test object is facing upwards Regardless of whether the inspection device is confidential on the front or back, the security strip or wire is long enough to sweep the antenna and / or electrode. The antenna and / or electrode may be a sliding device, a pressure roller, and / or a roller that serves to push the confidential document to be matched at a predetermined distance from the antenna and / or against the electrode during rapid transport. Cooperates with a kind of feed belt known per se. The operation of the sensor array, due to the progressive arrangement of the inspection device, near the optical and / or magnetic sensors and / or format sensors that normally operate to recognize the geometry, arrangement, dyes, and the like. Are performed simultaneously. The one or more antennas and / or electrodes are activated with high and / or low frequency energy and / or direct current, and one or more antennas and / or electrodes via security strips or wires. Receive a portion of the transmitted power. The voltage applied at one or more receiving antennas and / or receiving electrodes is changing. Certain conditions of movement, such as, for example, the speed of operation, for the authenticity and validity of securities or the validity of banknotes, are necessary for the test object to be compared in order to produce a comparable statement. is there. The antenna and / or the electrodes supply a voltage to the electronic evaluation circuit. The electronic evaluation circuit easily provides the comparison voltage in proportion to the signal pattern of the received voltage. Special filters and / or phase comparators can be used to block disturbances and external power and to prevent the main conductivity of the test object from affecting the test results. The output pulse of the electronic evaluation circuit is independent of the feed speed. The selectivity amplifier is further connected to an electronic evaluation circuit in order to take into account the particular selectivity of the verification device. Selective amplifiers convert the voltage resulting from the sensor array into an easily comparable voltage that depends on the amplitude response. In defining an electronic evaluation circuit for the class to be considered (conductivity assurance strip, or assurance wire, or some kind of conductivity point), an additional range of amplitudes may be set to an amplitude response much closer to the amplitude of the test signal. A preset and authenticity definition is obtained based on the difference between a predetermined preset amplitude range and the maximum possible amplitude of some objects to be matched. This means that recently distributed counterfeiting that produces a signal in a normal environment is detected as an evaluation signal and is detected as a counterfeit by the evaluation electronics according to the present invention. In the context of the present invention, determining all banknotes of a particular country with a special currency, for example a similar security strip, is provided by the evaluation electronics of the present invention by a definable time limit of the test signal amplitude, for example by a controller. Is performed for a given currency that is different from the interval of the amplitude response of all other currency. Money with evenly spaced test signal amplitudes is subject to additional tests, for example, by way of color recognition and / or color identification and / or magnets and / or format matching. For example, a recognition signal derived from a light barrier is combined with the signal of the sensor arrangement according to the invention and converted into a device-specific output pulse. A variant of the method involves checking a confidential document by applying power to one or more pairs of transmitting antennas in the phase shifting means. As a result of capacitive coupling between the transmitting antenna and the conductive indicia on the security strip and the receiving antenna located opposite the transmitting antenna, a credibility determination signal is generated at the input of the amplifier. Because of the lack of conductive strips in its effective range, there is no capacitive signal coupling between the second transmitting antenna and its receiving antenna that is powered beyond the phase range for the first transmitting antenna. Does not occur. Thus, this arrangement makes it possible to match continuous conductive strips. There is a further set of transmit and receive antennas, in that the lengths and distances from each other correspond to the conductive indicia of the security strip, as transferred from these antenna pairs. By moving the object to be matched at a predetermined distance with respect to the test sensor array, the specific amplitude and time that can be evaluated are provided from the receiving antenna to the evaluation technique. In this way, the inspection is performed so that a plurality of conductive marks insulated from each other can be recognized and evaluated. In this context, whether the insulation between the conductive marks is intentional, as in U.S. banknotes, or the uninterrupted conductivity, as in, for example, German banknotes It does not matter if it is the result of a break in the marking that occurs as a strip. The microcontroller can compare the number of obstructions with the stored value. By arranging several sets of transmitting and receiving antennas, and the associated evaluation electronics, it is possible to obtain reliable results with respect to the authenticity of confidential documents. The inspection device works reliably even if the object to be verified is shifted with respect to the verification device when feeding it into the device. If the transmitting and receiving antennas according to the invention are arranged over the working width of the entire processing device, the authenticity check is performed irrespective of the position of the test object. Thus, whether the confidential document is fed on the front side or the back side facing upwards and / or whether its security strip is arranged on the right or left side and / or arranged on the left and right with respect to the direction of movement It doesn't matter if it is fed at the specified location. In this way, different currencies can be matched for a format similar to the arrangement of their security strips with respect to the direction of movement. In addition, special arrangements of different securities, such as different kinds of security strips, as well as different currencies, also allow classification with respect to authenticity. In the banknote feed direction, further test sensors can be arranged before or after the test sensor arrangement according to the invention. In that case, the output signal of such a test sensor array is combined with the output signal according to the invention (double matching) and, for example, the software of the processing device when re-adapting to the matching device of the method according to the invention. No changes are required in. In addition to the claims, advantageous embodiments of the invention can also be taken from the description and the drawings, wherein individual features may be combined separately or jointly in any combination with any protection claimed herein. , Can be expressed as a protectable embodiment. Embodiments of the present invention are depicted in the drawings. FIG. 1 is a block circuit diagram of an evaluation circuit. FIG. 2 is a detection data graph of a bank note moving at different speeds. FIG. 3 is a special detection data graph of money. FIG. 4 is a detection data graph of some banknotes and counterfeits. FIG. 5 is a block circuit diagram of an evaluation circuit incorporating double matching. FIG. 6 is a cross-sectional view of a schematic representation of the verification device. FIG. 7 is a diagram showing the arrangement of the inspection sensors. FIG. 8 is a block circuit diagram of the verification device. FIG. 9 is a diagram showing the arrangement of the inspection sensor array in the processing device. The methods and arrangements described in detail for the various devices are based essentially on performing the processing steps of the capacitive coupling of the electrical signal from the transmitting antenna to the receiving antenna via the conductivity assurance material, making it easy to compare Amplification and conversion of the received signal, differing in amplitude and time response to possible signals, and comparing said signal with the current signal pattern which indicates and evaluates the authenticity of the confidential document matched in an appropriate form It is also based on things. A device coupled to the matching device transfers banknotes or securities into the area of the matching device. The light barrier further exploits the array of test sensors. The transmitting antenna is energized by high frequency energy. In the embodiment of the present application, the frequency is 6 MHz. As the security strip or wire passes through the inspection area, the receiving antenna absorbs a portion of the transmitted power. The HF voltage at the receiving antenna changes. The reason for this is, as is well known, due to the capacitive coupling between the transmitting and receiving antennas due to the conductivity of the security strip or wire. HF conductivity differs for different currencies. In order to be able to provide a currency-specific indication with the aid of an evaluation circuit, it is necessary in a single operation to provide constant feed conditions for all objects to be matched. An electronic evaluation circuit consisting essentially of an analog-to-digital converter and a controller or integrator 15, a trigger 16, a controller mono-flop 17, and / or an AND gate 18 is connected to a matching unit by means of a shielded connector. And the test sensor array is complete. An example of an electronic evaluation circuit is shown in FIG. Reference character 12 is an HF transmitter. Reference numeral 13 denotes an HF receiver that receives the transmitted power by the receiving antenna 9, and amplifies the signal as a signal specific to money and / or usable for authenticity. 15 is an integrator. 16 further receives the evaluation circuit activation signals from the light barrier 20 for the current signal and transmits them as time-coordinated pulses via the monoflop 17 as output signals to the test object determined to be authentic. As can be seen by the graphs a and b in FIG. 4 representing the passage of the banknote, the counterfeit 26 does not produce a comparable output signal on that part of the banknote that has been determined to be genuine. In addition to the arrangement of the test sensors in the area of the light barrier, the predetermined shield of the test sensor array of the electronic evaluation circuit, for protection from electric and electromagnetic fields, guarantees a high ratio of effective interfering signals and provides a certain banknote Coordinated with the forward feed by the conveyor belt at the feed speed, ensures the currency specific selectivity of the reconciliation device. A further advantage of the method according to the invention is that the moisture content and / or the degree of contamination of the test object and / or banknotes and / or securities is no longer a major cause of the obstruction. FIG. 6 is a cross-sectional view of the matching device used in the banknote processing device for the method described above. A housing support 1 is provided with a device support 2 for housing detection sensors arranged on a horizontal arm 3. The sensor arrangement is provided within the light barriers 4, 5 on the non-conductive support 6 of the arm 3. The support 6 has openings and / or punched holes for the passage of the light barriers 4,5. If the support 6 used is transparent, there is no need for openings and / or punched holes. The array of test sensors comprises a plurality of strip sensors 8. In the embodiment shown, there are two sensors, a strip sensor 8 acting as a transmitting antenna and a strip sensor 9 acting as a receiving antenna. The vertical length of the surface of the strip sensors 8, 9 in the direction perpendicular to the feed direction of the banknote 11 is determined by the action of the predetermined side of the banknote 11 on the front side or the back side of the banknote 11 facing upward. The security strip or wire is of a length that is independent of whether it passes through the matching device or not, and is further swept well across the strip sensors 8, 9 and directed under them through the matching device. The feed belt 10 extends under and parallel to the arm 3 at such a distance as to press the banknotes against the strip sensors 8, 9 during the rapid movement of the banknotes. The light barriers 4 and 5 are arranged between the feed belts 11 perpendicularly to the moving direction of the banknotes. The electronic evaluation circuit is also located in a shielded part of the processing device. In the embodiment shown, it is practically located in the area of the housing in which the paper thickness adjusting device is provided. The arrangement of the test sensor and the predetermined shielding of the electronic evaluation circuit from electric and electromagnetic fields, further comprising the arrangement of the test sensor array in the region of the light barrier, guarantee a high ratio of effective interfering signals, and The feed speed of a given bank note, together with the currency-specific selectivity of the reconciliation device, combine with forward guidance by the feed belt 10. A further advantage of the verification device according to the invention is that, for example, the moisture content and / or the degree of contamination of the test object no longer appear as major sources of disturbance. As can be seen in the direction of banknote movement (not shown in this embodiment), further test sensor arrangements, for example magnetic verification as shown in the block diagram of FIG. Before or after. In this case, the output signal of this sensor array is combined with the output signal of the test sensor array according to the invention, for example, without the need to change the software of the appropriate processing device when re-adapting the sensor array according to the invention. Is done. As shown in FIGS. 2 and 3, an evaluation circuit coupled to the test sensor array and the light barrier delivers a direct current that depends on the amplitude response of the received HF voltage. This is illustrated in the previous figure by the transmitted signal represented as graph a. FIG. 2 shows a graph detecting banknotes fed at different feed speeds. Graph a shows the transmission signal, and graph b shows the output signal of the electronic evaluation circuit. v ₁ Is equivalent to a feed speed of 500 banknotes / minute, and v _Two Is equivalent to a feed rate of 1,800 banknotes / minute. Graph b further illustrates how the banknote recognition signal provided by the light barrier is combined with the signal from the test sensor array and converted to a device-specific output pulse. This output pulse is independent of feed speed, as can be seen by comparing graph b in FIG. FIG. 3 shows a currency-specific detection graph of banknotes of different currency to be fed. Graph a further shows the transmitted signal from the test sensor array, while graph b shows the selectivity amplifier further coupled to the electronic evaluation circuit to enable currency specific selectivity of the verification device without additional sensors. 9 shows an evaluation signal. In FIG. 3, in the currency issued after 1990, DE means German currency, CH means Swiss currency, EG means Egyptian currency, and CH means Chinese Yuan. The amplitude response of the different received HF powers for different types of security strips is apparent in banknotes of different confidential documents and is therefore detected by the electronic evaluation circuit. If currency-specific signals need to be processed, the additional signals processed by the electronic evaluation circuit allow currency-specific classification, for example, by a controller. In a similar manner, in that the various classified documents are distinguished by different security strips or lines, counterfeiting is detected as long as they comprise a false security strip or line or at least a fragment based on them. Is done. FIG. 4 shows a detection graph of 11 banknotes in the confidential document counter. Banknotes numbered 21-25 and 27-31 are recognized as authentic. The inspection object numbered 26 is a forgery intentionally inserted into the verification result. No signal is supplied by the test sensor array for security strips or forged security strips. In practice, the banknote processing device is shut down when there is no signal or when the signal does not relate to banknotes, and counterfeit or unused bills are removed or placed mechanically distinct. If the verification device is further coupled to a test sensor array, the device-specific output pulse indicates the detection of a given security strip or line, and is output by a processing device, preferably an AND gate, to a further verification output signal. Be combined. If one of the authenticity signals is missing, the device is shut down and the operator removes the defective or counterfeit banknote. With a properly defined electronic evaluation circuit, a further possibility of use arises from the evaluation signal of the selective amplifier, as shown in FIG. For example, if in many processors used to classify various currencies, the amplitude limit A marked in FIG. 3 would be exceeded for all currencies matched and the speed v _Two The one with the authentic security strip according to the test sensor arrangement is detected. Special time t _k Is associated with each currency. The time t to distinguish individual currency _k = t ₁ ... t _Four (T _n T) is a currency-specific t _k It is defined as Thus, for example, t in German money _f Is the Swiss franc t _Two Which is selected to be greater than or t _f Is the t of Egyptian currency _Three It is a larger choice. T of german money _f Is the t of a currency not shown in FIG. _f Must be provided in the processing unit to provide additional currency-specific matching by conventional color recognition and / or formatting and / or magnetic matching. The individual coins thus classified are deposited in bins or storage boxes in a well-known manner. To match non-continuous conductivity assurance strips of a security, the processing unit comprises a test sensor array 54 of the kind shown in FIG. 7, wherein all the plurality of sensors are placed parallel to each other and perpendicular to the feed direction. Of the transmitting and receiving antennas. For matching, the banknotes are placed on a feed device that feeds through a processing device such that the longest length of security strip or wire in the banknotes is aligned well parallel to the feed direction. In other words, German banknotes are not arranged with the longest length aligned vertically enough in the direction of movement. The transmitting antennas A2, A3 and the receiving antenna A are arranged to face each other. From there, some transmitting antennas B2.I (I = 1 ... n) and some receiving antennas B1.I form an antenna pair. These pairs prevent double coupling of signals from one transmit antenna B1.I to a nearby but not the corresponding receive antenna B1.k (k-1 ... n, I <> k) Are moved from each other and lined up. The nearby transmitting antenna (B2.I, B.2.i + 1) and the corresponding receiving antenna (B1.I, B1.I + 1) are at a predetermined distance, rather than the transmitting antenna (B2.I) and its corresponding It is shifted by the distance to the receiving antenna (B1.I). To reduce jamming, pairs of antennas shifted diagonally from each other are rather arranged between the transmitting antennas A2, A3 and the receiving antenna A1. FIG. 8 shows a block circuit diagram of a verification device according to the invention in which the test sensor arrangement is energized as shown in FIG. If the confidential document is fed to a processing unit with a matching device according to the invention, it is activated by a light barrier or a smaller positioning sensor. The frequency generator 41 applies a voltage to the transmission antenna A2 via the phase shifter 42 and the transmission antenna A3. The phase shifted voltage application prevents the effects of disturbances from external energy and detects counterfeits that do not show a difference in conductivity. This is also realistic as a result of the changing characteristics of banknotes, for example, degradation and / or mechanical damage and / or moisture. At the same time, the n transmission antennas B.2i (I = 1 ... n) are supplied with voltages by the second frequency generator 43 and the second phase shifter 44. Transmit antennas B2.I arranged transversely and not in a straight line across the feed direction reduce the effects of disturbances from external energy, and receive antennas B1 .k (k = 1 ... A voltage is applied to the phase shift means to prevent capacitive double coupling to n, I <> k). To prevent signal distortion at the receiving antenna, the frequencies of the signals from the two generators are chosen such that there are no frequencies that are multiples of the other frequencies, or multiples of the difference between the two frequencies. During the collation, the capacitive coupling of the signal of the transmitting antenna A2 to the receiving antenna A1 is performed via a continuous connected strip of conductivity assurance, but the signal of the transmitting antenna A3 is not capacitively coupled to the receiving antenna A1. The minimum distance between the transmitting antenna A2 and the receiving antenna A1 is less than or equal to the maximum length of the conductive security strip in the smallest secure document to be matched. If the guarantee strip is never in the operating range of the transmitting antenna A2 and the receiving antenna A1 during the verification, the guarantee strip is placed in the operating range of the transmitting antenna A3 and the receiving antenna A1, and further functions are performed. The same is true for the case described above. In this case, a certain signal is present at the receiving antenna A1 by the rectifier 45 and the selective amplifier 46 sequentially generating a signal to the microcontroller 47. The microcontroller 47 performs credibility matching by comparing the signal from the selectivity amplifier 46 to a signal, for example, a special threshold stored in the microcontroller 47. If the threshold is exceeded, the microcontroller 47 classifies the object to be matched as an object having a continuous conductive wire, ie as authentic in the case of Deutsche Banknotes. If there are conductive marks in the security strip that are not detected by the transmitting and receiving antennas A2 and A1 due to their length, their distance is significantly greater than the distance between the transmitting and receiving antennas A2 and A1. Being small, it is possible to detect them by the arrangement of the transmitting antennas B2.I and the corresponding receiving antennas B1.I. For example, if the length of the conductive mark placed parallel to the confidential document feed direction is 1.5 mm, the distance between the transmitting antenna B2.I and the receiving antenna B1.I guarantees the capacitive coupling 1.3mm to be selected. During collation, the currency to be collated is moved at a predetermined speed in the effective range of the test sensor arrangement according to the invention. In the displaced arrangement of the transmitting antenna B2.I and the receiving antenna, there is a margin balance in the case of a vertical shift of the banknote with respect to the feed direction. The signals originating at the receiving antennas B1.I are sent to the microcontroller 47 via rectifiers 48 ... 50 and selective amplifiers 51 ... 53. The signals from the selective amplifiers 46, 51 ... 53 received by the microcontroller 47 are distinguished from their frequency and amplitude responses, depending on the structure and position of the security wire in the security document. In this way, classification of the secure documents is enabled by the microcontroller 47 based on comparing the frequency and / or the threshold value with a predetermined value stored in the microcontroller 47. These values are determined by manual entry, programming and / or comparison with parametric values based on already classified comparative securities. The microcontroller 47 generates a device-specific signal that is a property of the authenticity of the banknote to be verified. This classification signal of the microcontroller 47 is sent to a suitable display and / or a suitable interface of a processing device for further processing. In the same way, if different coins are distinguished by different security strips or fine lines, they are detected as counterfeit if they have counterfeit security strips or fine lines or just fragments based on them. The compact structure of the overall verification device, the sensors and the electronic evaluation circuit integrated in a single unit in more detail, and the added shielding offer further possibilities for reducing the more significant disturbances. The arrangement in the processor is such that the normal feeding of the banknote is not disturbed by the test sensor arrangement. A typical method of integrating an advanced matching device into a conventional processing device is shown in FIG. For this purpose, the test sensor array 54 consisting of the transmitting antennas A2, A3, B2.I and the receiving antennas A1, B1.I is integrated in the current guidance device 56. The test sensor array 54 is arranged tangentially with respect to the guidance device 56 or tangentially shifted with respect to the feed roll 55 in such a way that has a further guiding function in the area of the test sensor array 54. For that reason, the banknotes to be verified are fed into the operating range of the sensor without the additional pressing means. The test sensor array is tangentially arranged with respect to such a guiding device 56 such that the confidential documents to be matched and fed by the feed roller 55 are guided by the test sensor array 54 at predetermined intervals and at a predetermined speed. By means of suitable fasteners on the guiding device 56, in particular wobble screws, a certain distance is provided between the feed roller 55 and the guiding device 56 or the test sensor arrangement. The setting of the threshold values and the classification values is performed by switches not shown in the figure or by appropriate software of the microcontroller 47. In this way, the operator can change the classification value by simply operating a switch to match different currencies. In practice, the device is stopped by no signal appearing or by a signal not relating to the banknote and the forged or unused banknotes are removed. The impact of paper quality, degradation, moisture, etc. on the credibility classification is reduced by the lateral extension of the antenna array over the entire width of the confidential document. This also includes the possibility of classification into counterfeit, genuine banknotes and incompletely worn banknotes. This type of classification is performed by the selective evaluation of the amplitude and time response of the generated signal by the selective amplifiers 46, 51... 53 and by similar threshold values set by the evaluation microcontroller 47. The microcontroller 47 is calibrated manually, software controlled, or by checking a special calibration confidential document against a known credibility class. In the latter method, the calibration security document is verified by the verification device in the method described above. Instead of comparing the output signals of the selectivity amplifiers 46, 51 ... 53 with the signals stored in the microcontroller 47, they are stored in the microcontroller 47 as reference values. Another location for mounting the test sensor array 54 is disclosed in (Germany) Patent Application No. 195 18229.4. In accordance with the invention, the test sensor array 54 is located, for example, at the distal end of a round arcuate guidance device 56 as shown in FIG. Here again, the contact press of the test object by the pressing device and / or the inspection device required to produce the predetermined spacing is omitted. This possibility is used if it is not possible to provide a tangentially complemented test sensor array in the arcuate area of the guidance device 56. In the context of the present invention, the pressing object, such as a spring or a pressing roller, is supplemented, so that the test object itself is subjected to slight mechanical pressure. The method according to the invention has been described in the context of a secure document counting device with respect to a test sensor arrangement and an electronic evaluation circuit. However, it is noted that the invention is not limited to the details of the described embodiments, as changes and modifications may be claimed within the scope of the claims. Thus, many different implementations of an electronic evaluation circuit adapted to the specific operation of the selective amplifier are possible.

[Procedure for Amendment] Article 184-8, Paragraph 1 of the Patent Act [Date of Submission] February 14, 1997 [Contents of Amendment] Description Method and apparatus for collating confidential documents The present invention is described in the preamble of Claim 1. The present invention relates to a method and an apparatus for verifying or checking such a security document. Many processes, devices, methods and inspection systems are known not only to limit or count money, but also to determine the authenticity of confidential documents, check their validity, and determine their placement in processing equipment. . German Patent 1,223,594 describes a device for capacitive sensing image material in which sensing capacitors consisting of sensor electrodes are arranged on both sides of the path of movement of the image material. This device is not warranted to detect embedded strips, stamped or stuck conductive strips, ribbons or other small pieces. German Patent No. 1,774,290 describes an observation arrangement for automatically evaluating banknote-specific elements in a device for checking the authenticity of banknotes by means of capacitive electrode pairs arranged in a grid-like pattern. I have. This known observation arrangement does not allow an accurate determination of each specific element at the currently required processing speed, and in slower matching processing only the presence of such elements is detected, It is inadequate against currently known counterfeiting using conductive elements in a ticket. In German published specification 2,619,457, the magnetic properties of test strips provided in banknotes are measured. German Patent No. 2,834,287 describes checking the authenticity of a ferromagnetic security strip in a printed confidential document by using a magnetic field. These inspection methods are very slow and always require precise positioning of the object or strip to be verified. German Patent No. 2,760,165 describes a technically complex inspection device in which the authenticity of banknotes is determined by observing other inspection parts, in particular differences in thickness and fluorescence properties. Examining only these characteristics no longer corresponds to counterfeiting patterns currently in circulation. Counterfeit confidential documents, including water marks and fluorescent paper or dyes, are no longer recognized as counterfeit by this device. In particular, the read head of the processing device described in German published specifications Nos. 3,236,373 and 3,236,374 is to provide a sensitive document by forming a capacitor and introducing a ferroelectric material between the capacitive electrodes of the read element. Affects the change in the predetermined capacitance value for the above indicia. Even the read head is unsuitable for inspecting high-speed processing devices and the European banknotes currently in circulation. Determining the presence of conductive assurance strips by means of an untuned oscillator and a resonant circuit according to German Patent 2,912,712 is accepted due to the low reputation of reliability and the high technical complexity and complex structure. Absent. U.S. Pat. No. 5,308,992 describes the observation arrangement of optical and capacitive sensors, but requires accurate positioning of the test strip. The use of additional magnetic sensors has been proposed to improve the rate of error-free operation and to distinguish between different test objects (e.g. different currencies), creating more complex and expensive observation configurations doing. Subsequent to resorting the banknotes, the capacitive sensor is only capable of detecting the presence of a conductive security strip. German Patent No. 4,103,832 discloses a test arrangement in which capacitive sensors and / or electro-optical sensors and / or millimeter-wave sensors are arranged to match along a matching path. The subject matter of this disclosure relates specifically to testing the dielectric properties of banknotes. German Patent No. 4,325,027 describes a method and arrangement for checking the authenticity of banknotes in that the change in field strength resulting from bridging of high-frequency fields is evaluated by metal security strips. doing. Due to the limited sensitivity and low suppression of disturbance energy, it is suitable for use only at low speeds. In addition, the objects of the surface conductivity test and the wetness test are also recognized as authentic. Damage to the genuine banknote metal strip is not recognized because it would cause a false shutdown of the device. Due to the low sensitivity of the array, the distance between the electrode and the metal security strip of the banknote is small enough to prevent its use in a fast-acting banknote processor. Sequential arrangement of some such sensors is only possible at relatively large intervals such that the sensors do not affect each other. International Publication No. WO 94/22114 describes an apparatus for detecting conductive assurance fine wires made of metal. Here again, since the device is operated to measure the charge on the sensor electrodes, the objects of the surface conductivity test and the wetness test are detected as authentic. In addition, it does not support the classification of guaranteed wire of different length. European Patent Specification 0,204,574 describes a method for detecting magnetic printing designs by electromagnetic induction. Since even conventional copying machines can be loaded with conductive ink, this verification type is not reliable enough in view of today's counterfeit nature. An essential disadvantage of these known inspection methods and arrangements is their high technical complexity for detecting counterfeiting in banknotes that are rapidly fed through secure document processing equipment. And poor reliability. Disadvantages of the known observation arrangement for sensing the capacitive properties are that the sufficiently low capacitive resistance is only in the supplied low frequency range from 10 to 220 kHz and with a small gap between the electrode and the metal strip. It can only be built. Furthermore, in this frequency range, the effect of the dielectric charge is still insignificant, i.e., a material with a relatively high dielectric constant results in an increase in the capacitance and thus a decrease in the capacitive resistance between the antennas. Thus, for example, wet forgery is perceived as genuine. In practice, these arrangements, especially with respect to mechanized authenticity matching, have not been successful to date. European Patent No. 589,195 A2 discloses that a device having an excitation coil and a sensor coil is used to determine the authenticity of a test object by detecting a sensing area provided with a magnetic element having a high permeability with an allocated code. It describes how to derive from a given detection signal and that its authenticity is revealed when the detection signal and the assigned code match. This matching method can be used to some extent only on plastic cards, paper securities and a small number of non-European banknotes with magnets or magnetizable strips. Other matching methods described in European Patent Nos. 204,574 A2, 553,401 A1 and 506,023 A1 for the geometric and / or physical properties of the test object are classified according to the method of comparison. And can be used only with certain types of test objects, which are very complex and unacceptable as a single-action credibility verification method due to the desired high speed. Eliminating the disadvantages of known arrangements and methods by ensuring the inspection of specific test elements, for example various banknotes containing wet or intentionally moistened and / or soiled test objects And is used for money, distinguishes them from each other, has low technical complexity, and is effective to be executed in a retro-fit processing device. It is one of the objects of the present invention to satisfy the rapid throughput in the treatment apparatus. Conductive security wires or ribbons in banknotes or confidential documents (securities) or two-dimensionally formed security elements are used as unique inspection elements. It is a further object to configure an inspection unit that performs a method in which credibility matching is performed prior to classification based on money or the like. Developed a device that inspects confidential documents on assurance elements, including conductive ribbons or fine-wire-like strips, and inspects continuous conductive strips with multiple conductive areas electrically isolated from each other It is yet another object of the present invention to do so. An example of such a confidential document is current U.S. banknotes with security wires that maintain conductive properties isolated from each other. As a modern practice, the process by which such an inspection system recognizes not only high quality counterfeiting, but also genuine confidential documents of low quality, which in fact frequently occurs and which considerably hinders the operation of the processing device. Requires incorporation of equipment. In order to take advantage of the kind of capacitive coupling known per se, the method according to the invention for inspecting confidential documents comprises transmitting and amplifying an electrical signal from a transmitting antenna to a receiving antenna via a conductive element. provide. The conductive element is evaluated after an amplitude response after a predetermined time, converted into a signal pattern with easily comparable parameters and compared with the current signal pattern. In order to carry out the method with these steps described, an inspection device utilizing capacitive coupling requires a security strip or wire or a two-dimensional security element used in a banknote processing device, rather than a counting device. Suggested for bank notes, confidential documents, securities, and the like. The sensor array is located in the housing assembly near the optical and / or magnetic sensors and / or the format sensors. The device allows banknotes and / or securities to pass through the inspection device. The sensor arrangement comprises a plurality of antennas and / or electrodes. The vertical length of the surface area of the antenna and / or the electrodes in a direction perpendicular to the feed path, even when acting from a given side of the test object, also indicates that the test object is facing upwards Regardless of whether the inspection device is confidential on the front or back, the security strip or wire is long enough to sweep the antenna and / or electrode. The antenna and / or electrode may be a sliding device, a pressure roller, and / or a roller that serves to push the confidential document to be matched at a predetermined distance from the antenna and / or against the electrode during rapid transport. Cooperates with a kind of feed belt known per se. The operation of the sensor array by the progressive array of inspection devices near the optical and / or magnetic sensors and / or format sensors that normally operate to recognize geometry, arrangement, dyes, and the like. Are performed simultaneously. The one or more antennas and / or electrodes are activated with high and / or low frequency energy and / or direct current, and one or more antennas and / or electrodes via security strips or wires. Receive a portion of the transmitted power. The voltage applied at one or more receiving antennas and / or receiving electrodes is changing. Certain conditions of movement, such as, for example, the speed of operation, for the authenticity and validity of securities or the validity of banknotes, are necessary for the test object to be compared in order to produce a comparable statement. is there. The antenna and / or the electrodes supply a voltage to the electronic evaluation circuit. The electronic evaluation circuit easily provides the comparison voltage in proportion to the signal pattern of the received voltage. Special filters and / or phase comparators can be used to block disturbances and external power and to prevent the main conductivity of the test object from affecting the test results. The output pulse of the electronic evaluation circuit is independent of the feed speed. The selectivity amplifier is further connected to an electronic evaluation circuit in order to take into account the particular selectivity of the verification device. Selective amplifiers convert the voltage resulting from the sensor array into an easily comparable voltage that depends on the amplitude response. In defining an electronic evaluation circuit for the class to be considered (conductivity assurance strip, or assurance wire, or some kind of conductivity point), an additional range of amplitudes may be set to an amplitude response much closer to the amplitude of the test signal. A preset and authenticity definition is obtained based on the difference between a predetermined preset amplitude range and the maximum possible amplitude of some objects to be matched. This means that recently distributed counterfeiting that produces a signal in a normal environment is detected as an evaluation signal and is detected as a counterfeit by the evaluation electronics according to the present invention. In the context of the present invention, determining all banknotes of a particular country with a special currency, for example a similar security strip, is provided by the evaluation electronics of the present invention by a definable time limit of the test signal amplitude, for example by a controller. Is performed for a given currency that is different from the interval of the amplitude response of all other currency. Money with evenly spaced test signal amplitudes is subject to additional tests, for example, by way of color recognition and / or color identification and / or magnets and / or format matching. For example, a recognition signal derived from a light barrier is combined with the signal of the sensor arrangement according to the invention and converted into a device-specific output pulse. A variant of the method involves checking a confidential document by applying power to one or more pairs of transmitting antennas in the phase shifting means. As a result of capacitive coupling between the transmitting antenna and the conductive indicia on the security strip and the receiving antenna located opposite the transmitting antenna, a credibility determination signal is generated at the input of the amplifier. Due to the lack of conductive strips in its effective range, there is no capacitive signal coupling between the second transmitting antenna and its receiving antenna powered beyond the phase range with respect to the first transmitting antenna. Does not occur. In this way, this arrangement makes it possible to match continuously connected conductive strips. There is a further set of transmit and receive antennas, in that the lengths and distances from each other correspond to the conductive indicia of the security strip, as transferred from these antenna pairs. By moving the object to be matched at a predetermined distance with respect to the test sensor array, the specific amplitude and time that can be evaluated are provided from the receiving antenna to the evaluation technique. In this way, the inspection is performed so that a plurality of conductive marks insulated from each other can be recognized and evaluated. In this context, whether the insulation between the conductive marks is intentional, as in U.S. banknotes, or the uninterrupted conductivity, as in, for example, German banknotes It does not matter if it is the result of a break in the marking that occurs as a strip. The microcontroller can compare the number of obstructions with the stored value. By arranging several sets of transmitting and receiving antennas, and the associated evaluation electronics, it is possible to obtain reliable results with respect to the authenticity of confidential documents. The inspection device works reliably even if the object to be verified is shifted with respect to the verification device when feeding it into the device. If the transmitting and receiving antennas according to the invention are arranged over the working width of the entire processing device, the authenticity check is performed irrespective of the position of the test object. Therefore, whether the confidential document is fed on the front side or the back side facing upwards and / or whether its security strip is located on the right or left side, and / or left and right with respect to the direction of movement It doesn't matter if it is fed at the specified location. In this way, different currencies can be matched for a format similar to the arrangement of their security strips in the direction of movement. In addition, special arrangements of different securities, such as different kinds of security strips, but also different currencies, also allow classification with respect to authenticity. In the direction of travel of the banknote, further test sensors can be arranged before or after the test sensor arrangement according to the invention. In that case, the output signal of such a test sensor array is combined with the output signal according to the invention (double matching) and, for example, the software of the processing device when re-adapting to the matching device of the method according to the invention. No changes are required in. In addition to the claims, advantageous embodiments of the invention can also be taken from the description and the drawings, wherein individual features may be combined separately or jointly in any combination with any protection claimed herein. , Can be expressed as a protectable embodiment. Embodiments of the present invention are depicted in the drawings. FIG. 1 is a block circuit diagram of an evaluation circuit. FIG. 2 is a detection data graph of a bank note moving at different speeds. FIG. 3 is a special detection data graph of money. FIG. 4 is a detection data graph of some banknotes and counterfeits. FIG. 5 is a block circuit diagram of an evaluation circuit incorporating double matching. FIG. 6 is a cross-sectional view of a schematic representation of the verification device. FIG. 7 is a diagram showing the arrangement of the inspection sensors. FIG. 8 is a block circuit diagram of the verification device. FIG. 9 is a diagram showing the arrangement of the inspection sensor array in the processing device. The methods and arrangements described in detail for the various devices are based essentially on performing the processing steps of the capacitive coupling of the electrical signal from the transmitting antenna to the receiving antenna via the conductivity assurance material, making it easy to compare Amplification and conversion of the received signal, differing in amplitude and time response to possible signals, and comparing said signal with the current signal pattern which indicates and evaluates the authenticity of the confidential document matched in an appropriate form It is also based on things. A device coupled to the matching device transfers banknotes or securities into the area of the matching device. The light barrier further exploits the array of test sensors. As can be seen by the graphs a and b in FIG. 4 where the transmitting antenna is energized by high frequency energy, the counterfeit 26 produces a comparable output signal on that portion of the banknote that has been determined to be genuine. do not do. In addition to the arrangement of the test sensors in the area of the light barrier, the predetermined shield of the test sensor array of the electronic evaluation circuit, for protection from electric and electromagnetic fields, guarantees a high ratio of effective interfering signals and provides a certain banknote Coordinated with the forward feed by the conveyor belt at the feed speed, ensures the currency specific selectivity of the reconciliation device. A further advantage of the method according to the invention is that the moisture content and / or the degree of contamination of the test object and / or banknotes and / or securities is no longer a major cause of the obstruction. FIG. 6 is a cross-sectional view of the matching device used in the banknote processing device for the method described above. A housing support 1 is provided with a device support 2 for housing detection sensors arranged on a horizontal arm 3. The sensor arrangement is provided within the light barriers 4, 5 on the non-conductive support 6 of the arm 3. The support 6 has openings and / or punched holes for the passage of the light barriers 4,5. If the support 6 used is transparent, there is no need for openings and / or punched holes. The array of test sensors comprises a plurality of strip sensors 8. In the embodiment shown, there are two sensors, a strip sensor 8 acting as a transmitting antenna and a strip sensor 9 acting as a receiving antenna. The vertical length of the surface of the strip sensors 8, 9 in a direction perpendicular to the direction of movement of the banknote 11 is different from the length of the surface of the banknote 11 facing the front side or the back side of the banknote 11 in the operation of the predetermined side surface. The security strip or wire is of a length that is independent of whether it passes through the matching device or not, and is further swept well across the strip sensors 8, 9 and directed under them through the matching device. The feed belt 10 extends under and parallel to the arm 3 at such a distance as to press the banknotes against the strip sensors 8, 9 during the rapid movement of the banknotes. The light barriers 4 and 5 are arranged between the feed belts 11 perpendicularly to the moving direction of the banknotes. The electronic evaluation circuit is also located in a shielded part of the processing device. In the embodiment shown, it is practically located in the area of the housing in which the paper thickness adjusting device is provided. The arrangement of the test sensor and the predetermined shielding of the electronic evaluation circuit from electric and electromagnetic fields, further comprising the arrangement of the test sensor array in the region of the light barrier, guarantee a high ratio of effective interfering signals, and The feed speed of a given bank note, together with the currency-specific selectivity of the reconciliation device, combine with forward guidance by the feed belt 10. A further advantage of the verification device according to the invention is that, for example, the moisture content and / or the degree of contamination of the test object no longer appear as major sources of disturbance. As can be seen in the direction of banknote movement (not shown in this embodiment), further test sensor arrangements, for example magnetic verification as shown in the block diagram of FIG. Before or after. In this case, the output signal of this sensor array is combined with the output signal of the test sensor array according to the invention, for example, without the need to change the software of the appropriate processing device when re-adapting the sensor array according to the invention. Is done. As shown in FIGS. 2 and 3, an evaluation circuit coupled to the test sensor array and the light barrier delivers a direct current that depends on the amplitude response of the received HF voltage. This is illustrated in the previous figure by the transmitted signal represented as graph a. FIG. 2 shows a graph detecting banknotes fed at different feed speeds. Graph a shows the transmission signal, and graph b shows the output signal of the electronic evaluation circuit. v _t is equivalent to the feed speed of 500 sheets / minute tickets bank, v ₂ corresponds to the feed speed of 1,800 sheets / min banknotes. Graph b further illustrates how the banknote recognition signal provided by the light barrier is combined with the signal from the test sensor array and converted to a device-specific output pulse. This output pulse is independent of feed speed, as can be seen by comparing graph b in FIG. FIG. 3 shows a currency-specific detection graph of banknotes of different currency to be fed. Graph a further shows the transmitted signal from the test sensor array, while graph b shows the selectivity amplifier further coupled to the electronic evaluation circuit to enable currency specific selectivity of the verification device without additional sensors. 9 shows an evaluation signal. In FIG. 3, in the currency issued after 1990, DE means German currency, CH means Swiss currency, EG means Egyptian currency, and CH means Chinese Yuan. The amplitude response of the different received HF powers for different types of security strips is apparent in banknotes of different confidential documents and is therefore detected by the electronic evaluation circuit. If currency-specific signals need to be processed, the additional signals processed by the electronic evaluation circuit allow currency-specific classification, for example, by a controller. In a similar manner, in that the various classified documents are distinguished by different security strips or lines, counterfeiting is detected as long as they comprise a false security strip or line or at least a fragment based on them. Is done. FIG. 4 shows a detection graph of 11 banknotes in the confidential document counter. Banknotes numbered 21-25 and 27-31 are recognized as authentic. The inspection object numbered 26 is a forgery intentionally inserted into the verification result. No signal is supplied by the test sensor array for security strips or forged security strips. In practice, the banknote processing device is shut down when there is no signal or when the signal does not relate to banknotes, and counterfeit or unused bills are removed or placed mechanically distinct. If the verification device is further coupled to a test sensor array, the device-specific output pulse indicates the detection of a given security strip or line, and is output by a processing device, preferably an AND gate, to a further verification output signal. Be combined. If one of the authenticity signals is missing, the device is shut down and the operator removes the defective or counterfeit banknote. With a properly defined electronic evaluation circuit, a further possibility of use arises from the evaluation signal of the selective amplifier, as shown in FIG. For example, if in many processors used to classify various currencies, the amplitude limit A marked in FIG. 3 would be exceeded for all coins checked and at speed v ₂ Those with genuine security strips depending on the test sensor array are detected. Special time t _k is associated with each currency. In order to distinguish individual money, the time t _k = t ₁ ... T ₄ (up to t _n ) is defined as t _k specific to money. Thus, for example, t _f in German currency is selected to be greater than t _{2 in} Swiss francs, or t _f in Swiss francs is selected to be greater than t _{3 in} Egyptian currency. The t _f German money, since equal must be selected to t _f of money which is not shown in FIG. 3 as possible, in the processing unit, further by conventional color recognition and / or format and / or magnetic verification money It will be necessary to provide a unique match. The individual coins thus classified are deposited in bins or storage boxes in a well-known manner. To match the non-continuous conductivity assurance strips of the security, the processing device comprises a test sensor array 54 of the kind shown in FIG. 7, wherein all the plurality of test sensors are placed parallel to one another and perpendicular to the direction of movement. Of the transmitting and receiving antennas. For matching, the banknotes are placed on a feed device that feeds through a processing device such that the longest length of security strip or wire in the banknotes is aligned well parallel to the direction of movement. In other words, German banknotes are not arranged with the longest length aligned vertically enough in the direction of movement. The transmitting antennas A2, A3 and the receiving antenna A are arranged to face each other. From there, some transmitting antennas B2.I (I = 1 ... n) and some receiving antennas B1.I form an antenna pair. These pairs prevent double coupling of the signal from one transmit antenna B1.I to a nearby but not the corresponding receive antenna B1.k (k-1 ... n, I <> k) Are moved from each other and lined up. The nearby transmitting antenna (B2.I, B.2.i + 1) and the corresponding receiving antenna (B1.I, B1.I + 1) are at a predetermined distance, rather than the transmitting antenna (B2.I) and its corresponding It is shifted by the distance to the receiving antenna (B1.I). To reduce jamming, pairs of antennas shifted diagonally from each other are rather arranged between the transmitting antennas A2, A3 and the receiving antenna A1. FIG. 8 shows a block circuit diagram of a verification device according to the invention in which the test sensor arrangement is energized as shown in FIG. If the confidential document is fed to a processing unit with a matching device according to the invention, it is activated by a light barrier or a smaller positioning sensor. The frequency generator 41 applies a voltage to the transmission antenna A2 via the phase shifter 42 and the transmission antenna A3. The phase shifted voltage application prevents the effects of disturbances from external energy and detects counterfeits that do not show a difference in conductivity. This is also realistic as a result of the changing characteristics of banknotes, for example, degradation and / or mechanical damage and / or moisture. At the same time, the n transmission antennas B.2i (I = 1 ... n) are supplied with voltages by the second frequency generator 43 and the second phase shifter 44. The transmitting antennas B2.I arranged transversely and not linearly in the direction of movement are used to reduce the effects of disturbances from external energy and to receive antennas B1.k (k = 1 ... A voltage is applied to the phase shift means to prevent capacitive double coupling to n, I <> k). To prevent signal distortion at the receiving antenna, the frequencies of the signals from the two generators are chosen such that there are no frequencies that are multiples of the other frequencies, or multiples of the difference between the two frequencies. During the collation, the capacitive coupling of the signal of the transmitting antenna A2 to the receiving antenna A1 is performed via a continuous connected strip of conductivity assurance, but the signal of the transmitting antenna A3 is not capacitively coupled to the receiving antenna A1. The minimum distance between the transmitting antenna A2 and the receiving antenna A1 is less than or equal to the maximum length of the conductive security strip in the smallest secure document to be matched. If the guarantee strip is never in the operating range of the transmitting antenna A2 and the receiving antenna A1 during the verification, the guarantee strip is placed in the operating range of the transmitting antenna A3 and the receiving antenna A1, and further functions are performed. The same is true for the case described above. In this case, a certain signal is present at the receiving antenna A1 by the rectifier 45 and the selective amplifier 46 sequentially generating a signal to the microcontroller 47. The microcontroller 47 performs credibility matching by comparing the signal from the selectivity amplifier 46 to a signal, for example, a special threshold stored in the microcontroller 47. If the threshold is exceeded, the microcontroller 47 classifies the object to be matched as an object having a continuous conductive wire, ie as authentic in the case of Deutsche Banknotes. If there are conductive marks in the security strip that are not detected by the transmitting and receiving antennas A2 and A1 due to their length, their distance is significantly greater than the distance between the transmitting and receiving antennas A2 and A1. Being small, it is possible to detect them by the arrangement of the transmitting antennas B2.I and the corresponding receiving antennas B1.I. For example, if the length of the conductive mark placed parallel to the direction of movement of the confidential document is 1.5 mm, the distance between the transmitting antenna B2.I and the receiving antenna B1.I guarantees the capacitive coupling 1.3mm to be selected. During collation, the currency to be collated is moved at a predetermined speed in the effective range of the test sensor arrangement according to the invention. In the shifted arrangement of the transmitting antenna B2.I and the receiving antenna, there is a margin balance in the case of a vertical shift of the banknote with respect to the direction of movement. The signals produced at the receiving antennas B1.I are sent to the microcontroller 47 via rectifiers 48 ... 50 and selective amplifiers 51 ... 53. The signals from the selective amplifiers 46, 51 ... 53 received by the microcontroller 47 are distinguished from their frequency and amplitude responses, depending on the structure and position of the security wire in the security document. In this way, classification of the secure documents is enabled by the microcontroller 47 based on comparing the frequency and / or the threshold value with a predetermined value stored in the microcontroller 47. These values are determined by manual entry, programming and / or comparison with parametric values based on already classified comparative securities. The microcontroller 47 generates a device-specific signal that is a property of the authenticity of the banknote to be verified. This classification signal of the microcontroller 47 is sent to a suitable display and / or a suitable interface of a processing device for further processing. In the same way, if different coins are distinguished by different security strips or fine lines, they are detected as counterfeit if they have counterfeit security strips or fine lines or just fragments based on them. The compact structure of the overall matching device, the sensors and the electronic evaluation circuit integrated in a single unit in more detail, and the added shielding offer further possibilities for reducing the more significant disturbances. The arrangement in the processor is such that the normal feeding of the banknote is not disturbed by the test sensor arrangement. A typical method of integrating an advanced matching device into a conventional processing device is shown in FIG. For this purpose, the test sensor array 54 consisting of the transmitting antennas A2, A3, B2.I and the receiving antennas A1, B1.I is integrated in the current guidance device 56. The test sensor array 54 is arranged tangentially with respect to the guidance device 56 or tangentially shifted with respect to the feed roll 55 in such a way that has a further guiding function in the area of the test sensor array 54. For that reason, the banknotes to be verified are fed into the operating range of the sensor without the additional pressing means. The test sensor array is tangentially arranged with respect to such a guiding device 56 such that the confidential documents to be matched and fed by the feed roller 55 are guided by the test sensor array 54 at predetermined intervals and at a predetermined speed. By means of suitable fasteners on the guiding device 56, in particular wobble screws, a certain distance is provided between the feed roller 55 and the guiding device 56 or the test sensor arrangement. The setting of the threshold values and the classification values is performed by switches not shown in the figure or by appropriate software of the microcontroller 47. In this way, the operator can change the classification value by simply operating a switch to match different currencies. In practice, the device is stopped by no signal appearing or by a signal not relating to the banknote and the forged or unused banknotes are removed. The impact of paper quality, degradation, moisture, etc. on the credibility classification is reduced by the lateral extension of the antenna array over the entire width of the confidential document. This also includes the possibility of classification into counterfeit, genuine banknotes and incompletely worn banknotes. This type of classification is performed by the selective evaluation of the amplitude and time response of the generated signal by the selective amplifiers 46, 51... 53 and by similar threshold values set by the evaluation microcontroller 47. The microcontroller 47 is calibrated manually, software controlled, or by checking a special calibration confidential document against a known credibility class. In the latter method, the calibration security document is verified by the verification device in the method described above. Instead of comparing the output signals of the selectivity amplifiers 46, 51 ... 53 with the signals stored in the microcontroller 47, they are stored in the microcontroller 47 as reference values. Another location for mounting the test sensor array 54 is disclosed in (Germany) Patent Application No. 195 18 229.4. In accordance with the invention, the test sensor array 54 is located, for example, at the distal end of a round arcuate guidance device 56 as shown in FIG. Here again, the contact press of the test object by the pressing device and / or the inspection device required to produce the predetermined spacing is omitted. This possibility is used if it is not possible to provide a tangentially complemented test sensor array in the arcuate area of the guidance device 56. In the context of the present invention, the pressing object, such as a spring or a pressing roller, is supplemented, so that the test object itself is subjected to slight mechanical pressure. The method according to the invention has been described in the context of a secure document counting device with respect to a test sensor arrangement and an electronic evaluation circuit. However, it is noted that the invention is not limited to the details of the described embodiments, as changes and modifications may be claimed within the scope of the claims. Thus, many different implementations of an electronic evaluation circuit adapted to the specific operation of the selective amplifier are possible. A method wherein the phase comparator is arranged after the selective amplifier as well as a special filter and evaluation unit for blocking disturbance and external energy in a method which is force-directed through a band. 2. The electronic evaluation circuit, consisting of a digital-to-analog converter and a controller or integrator (15), a trigger (16), a monoflop (17), and / or an AND gate (18), may have an amplitude limit exceeded (A) and / or money specific time t _k, the method of claim 1, wherein the determined based on signal characteristics at the output of the selective amplifier (14). 3. The method according to claim 1, wherein the credibility classification is performed by the telepresence evaluation circuit by setting an amplitude limit (A) for the credibility of the currency to be matched. 4. Classification of different banknotes and / or classified documents is performed by the electronic evaluation circuit, preferably by means of a controller, by setting a currency-specific time (t _k ), the times t ₁ ..t _k−1 , t _k the method of claim 1 or 2, characterized in that the inspection object having a _{+1 ..t n} are processed. 5. The method of claim 4, wherein the test to be added in the money with the same time (t _k) is characterized in that it is performed in accordance with authenticity. 6. The evaluation electronics, or rather the one or more controllers, emits device-specific signals for individually sorting and placing objects in special slots or stacked containers by means of time and / or voltage comparisons. The method according to claim 1 or 2, wherein 7. In a direction intersecting the direction of movement of the test object, the antenna and / or the electrode are parallel to a predetermined lateral action of the test object, and are located on the front or back surface where the test object is facing upward, and Irrespective of whether they pass through or not, they are of two-dimensional length and are characterized in that the security strip or wire sweeps the antenna and / or electrode in contact therewith at any given gap. The method according to claim 1 or 2, wherein 8. A method according to one or more of the preceding claims, wherein the additional matching is performed as a result of being coupled to the signal of the evaluation circuit by an AND gate without the need for software modification of the predetermined processing unit. 9. 9. Apparatus for collating confidential documents with conductive assurance strips, thin lines or two-dimensionally structured assurance material and performing the method according to one or more of claims 1 to 8, comprising: Forming one or more test areas in one or more planes in the vicinity of the optical and / or magnetic sensors and / or format sensors that activate the test sensor array therein; A plurality of sensors for coupling the antenna with energy in a high frequency range across the test object, depending on the geometry and / or conductivity of the test object, and with the antenna (B1.I) The minimum distance between the corresponding receiving antenna (B1.I) and the transmitting antenna (B2.I) is between one of the transmitting antennas (A2, A3) and the receiving antenna (A1). Is less than the first distance of And devices. 14. Some transmitting antennas (A2, A3, B2.1..B2.n) and receiving antennas (A1, B1.1 .. B1.n) are arranged over the full width of the feed path for confidential documents. 14. The device according to claim 13, wherein: 15． The transmitting antennas (A2, A3, B2.1..B2.n) and the receiving antennas (A1, B1.1..B1.n) are arranged parallel to each other in a plane adjacent to each other, and the authenticity verification of confidential documents can be performed. Apparatus according to claim 13 or 14, characterized in that it is performed independently of the sides and edges with respect to the edges of two parallel confidential documents. 16． Receiving antennas (B1.1..B1.n) and transmitting antennas (B2.1..B2.n) moved in parallel and / or laterally are aligned so that each assurance element to be verified is Irrespective of the arrangement, the receiving antennas (B1.1..B1.n) and the corresponding transmitting antennas (B2.1..B2.n) are arranged in a gap separated by a relationship such that they sweep. Item 14. The device according to Item 13. 17． 14. Device according to claim 13, characterized in that the longest side of the transmitting antenna (B2.I) and the longest side of the corresponding receiving antenna (B1.I) correspond to the width of the conductive marking of the security strip. 18． By means of rectifiers (45, 48..50) and selective amplifiers (46, 51..53) operable or software controlled switch and setting elements, in particular selective amplifiers (46, 51..53) Device according to claim 13, characterized in that the microcontrollers (47) are arranged such that the output signals are combined or logically joined. 19. By means of rectifiers (45,48..50) and selective amplifiers (46,51..53) operable or software controlled switch and setting elements, especially the different types and types of confidential documents and the degree of fraying 14. Device according to claim 13, characterized in that the microcontroller (47) is arranged such that changes between are performed without changing the arrangement of the sensors. 20. The minimum distance between the two transmitting antennas (B2.I) in a row is greater than or equal to the minimum distance between the two conductive and insulated markings on the security strip, and the element change is based on the antenna (A3 14. The apparatus according to claim 13, wherein) are arranged to be used as either a transmitting or receiving antenna depending on the feed of the confidential document to be matched. twenty one. Software or manually controlled switch element wherein one or more transmitting antennas (B2.I) and corresponding receiving antennas (B1.I) are selectively activated or deactivated. Item 14. The device according to Item 13. [Procedure of Amendment] Article 184-8, Paragraph 1 of the Patent Act [Date of Submission] April 18, 1997 [Details of Amendment] In the embodiment of the present application, the frequency is 6 MHz. As the security strip or wire passes through the inspection area, the receiving antenna absorbs a portion of the transmitted power. The HF voltage at the receiving antenna changes. The reason for this is, as is well known, due to the capacitive coupling between the transmitting and receiving antennas due to the conductivity of the security strip or wire. HF conductivity differs for different currencies. In order to be able to provide a currency-specific indication with the aid of an evaluation circuit, it is necessary in a single operation to provide constant feed conditions for all objects to be matched. An electronic evaluation circuit consisting essentially of an analog-to-digital converter and controller or integrator 15, a trigger 16, a controller mono-flop 17, and, if necessary, an AND gate 18, is collated by a shielded connector. The unit and test sensor array are completed. An example of an electronic evaluation circuit is shown in FIG. Reference character 12 is an HF transmitter. Reference numeral 13 denotes an HF receiver that receives the transmitted power by the receiving antenna 9, and amplifies the signal as a signal specific to money and / or usable for authenticity. 15 is an integrator. 16 further receives the evaluation circuit activation signals from the light barrier 20 for the current signal and transmits them as time-coordinated pulses via the monoflop 17 as output signals to the test object determined to be authentic. Expressing the passage of banknotes Claims 1. Bridging electromagnetic fields with conductive assurance strips, tapes, wires or two-dimensionally assured materials, using the following evaluation electronics as well as capacitive coupling between transmitter and receiver: A method for inspecting confidential documents by transmission of energy between a transmitter and a receiver according to Claim 1, wherein several antennas arranged in one or more planes and functioning as transmitting and receiving sensors are provided to the processing unit. Forming an inspection area in the area of the provided normal optical sensor, spatially harmonizing with the capacitive inspection sensor circuit in the processing device, activating the inspection sensor circuit, and providing a magnetic field in connection with the antenna; Energy is transmitted across the test object depending on the test object geometry and / or conductivity, and some antennas are at least in different phase positions. Energized, followed by transmission energy to the selective amplifier (14), to suppress interfering energy and external energy in order to suppress the main conductivity of the test object, e.g. banknotes and prevent interfering energy Phase comparators at the output of some amplifiers, as well as special filters and evaluation units, are arranged so that they can classify conductive assurance strips, tapes, wires or two-dimensionally constructed assurance materials, thereby testing The method according to claim 1, wherein the object is moved during the matching operation via the examination area at a lateral position that is not force-directed. 2. The electronic evaluation circuit, consisting of a digital-to-analog converter and a controller or integrator (15), a trigger (16), a monoflop (17), and / or an AND gate (18), may have an amplitude limit exceeded (A) and / or money specific time t _k, the method of claim 1, wherein the determined based on signal characteristics at the output of the selective amplifier (14). 3. The method according to claim 1, wherein the authenticity classification is performed by an electronic evaluation circuit by setting an amplitude limit (A) for the authenticity of the currency to be matched. 4. Classification of different banknotes and / or classified documents is performed by the electronic evaluation circuit, preferably by means of a controller, by setting a currency-specific time (t _k ), the times t ₁ ..t _k−1 , t _k the method of claim 1 or 2, characterized in that the inspection object having a _{+1 ..t n} are processed. 5. The method of claim 4, wherein the test to be added in the money with the same time (t _k) is characterized in that it is performed in accordance with authenticity. 6. The evaluation electronics, or rather the one or more controllers, emits device-specific signals for individually sorting and placing objects in special slots or stacked containers by means of time and / or voltage comparisons. The method according to claim 1 or 2, wherein 7. In a direction intersecting the direction of movement of the test object, the antenna and / or the electrode are parallel to a predetermined lateral action of the test object, and are located on the front or back surface where the test object is facing upward, and Irrespective of whether they pass through or not, they are of two-dimensional length and are characterized in that the security strip or wire sweeps the antenna and / or electrode in contact therewith at any given gap. The method according to claim 1 or 2, wherein 8. 3. The method as claimed in claim 1, wherein the additional test is performed as a result of being coupled to the signal of the evaluation electronics by an AND gate without the need for a software modification of the processing unit. 9. Capacitive coupling and energy transmission between the transmitter and receiver by bridging the electromagnetic field with conductive assurance strips, wires, or two-dimensionally assured materials, and for evaluation electronics An apparatus for inspecting confidential documents having elements and performing the method of claim 1, wherein a conventional optical sensor is provided in the processing unit for activating the capacitive inspection sensor array, A test area formed by several sensors arranged in the plane of the antenna and functioning as transmitting and receiving antennas, a selective amplifier (14), and thereby a phase comparator connected to the output; Special filters to block energy, as well as analog-to-digital converters and controllers or integrators (15), triggers (16), controller monoflops (17) and An electronic evaluation circuit consisting essentially of an AND gate, if necessary, during the verification operation, by means of a fastening device and / or a feed belt (10), rollers arranged in the area, A device characterized by being arranged for movement by a sensor at a predetermined contact in an undefined lateral arrangement. Ten. The sensor serving as a transmitting or receiving antenna is characterized in that it is configured as a strip sensor (8; 9) in one plane or in two planes arranged oppositely and / or symmetrically. An apparatus according to claim 9. 11． 10. The strip sensor (8; 9) comprises cavities and / or apertures and / or windows, or such is arranged adjacent to the strip sensor (8; 9). Or the device according to 10. 12． 12. The apparatus according to claim 9, wherein the sensors in the inspection unit are arranged symmetrically with respect to the inspection area and / or security strips, wires and / or tapes of the object to be matched. 13. Capacitive coupling and energy transmission between the transmitter and receiver by bridging the electromagnetic field with conductive assurance strips, wires, or two-dimensionally assured materials, and for evaluation electronics An apparatus for inspecting a confidential document having an element and performing the method according to claim 1, comprising a plurality of transmitting antennas (A2, A3, B2.1..B2.n) and a plurality of transmitting antennas forming an inspection sensor array. The receiving antennas (A1, B1.1..B1.n) are provided with a plurality of conductive areas insulated from one another and arranged in such a way that the conductive assurance strips can be matched, whereby the test sensor arrangement (54 ) Are arranged such that they are transferred parallel to the arcuate derivative (56) or parallel to the feed roller (55), with respect to the direction of the longest length of the security strip. Vertically aligned with the direction of movement of the confidential documents to be matched, Two transmitting antennas (A2, A3) energized in opposing phases having high or high frequency energy, and one or more opposing receiving antennas (A1) and, between them, a transmitting antenna (A1). A2, A3), some transmit antennas (B2.1..B2.n) shifted parallel and some receive antennas (B1..B2.n) parallel to the transmit antennas (B2.1..B2.n). 1..B1.n), whereby the nearby transmitting antennas (B2.I..B2.I + 1) and the corresponding receiving antennas (B1.I, B1.I + 1) have a predetermined distance, rather Receive antenna corresponding to antenna (B2.I)

────────────────────────────────────────────────── ─── Continuation of front page    (31) Priority claim number 196 09 405.4 (32) Priority date February 29, 1996 (33) Priority country Germany (DE) (81) Designated countries EP (AT, BE, CH, DE, DK, ES, FI, FR, GB, GR, IE, IT, L U, MC, NL, PT, SE), OA (BF, BJ, CF) , CG, CI, CM, GA, GN, ML, MR, NE, SN, TD, TG), AP (KE, LS, MW, SD, S Z, UG), AM, AT, AU, BB, BG, BR, B Y, CA, CH, CN, CZ, DE, DK, EE, ES , FI, GB, GE, HU, JP, KE, KG, KP, KR, KZ, LK, LR, LT, LU, LV, MD, M G, MN, MW, MX, NO, NZ, PL, PT, RO , RU, SD, SE, SI, SK, TJ, TR, TT, UA, US, UZ, VN

Claims (1)

[Claims] 1. Confidential documents with conductive assurance strips, tapes, wires or two-dimensionally constructed assurance materials by utilizing the capacitive coupling between the transmitter and receiver as well as the associated evaluation electronics. A spatially corresponding test sensor array in the processing device and one or more optical sensors and / or magnetic sensors and / or format sensors in the area of the test sensor array. The plurality of antennas and / or electrodes arranged in a plane and functioning as transmitting and receiving sensors create one or more inspection images, in high and / or low frequency ranges and / or as direct current. Energy is transmitted across the object by the antenna and / or electrode pair depending on the geometry and / or conductivity of the object, and Energy is transmitted by one or more antennas and / or electrodes at the same or different phase positions to the combined selectivity amplifier (14) and only suppresses the main conductivity of the test object, for example banknotes. Instead, in order to prevent disturbing energy, a classification of the conductive assurance strip, tape, wire or two-dimensionally constructed assurance material of the inspection object is performed, while the inspection object is in a collation operation. A phase comparator is arranged after said selective amplifier, as well as a special filter and an evaluation unit for blocking disturbance and external energy in a manner that is guided through the examination area without predetermined lateral positioning. A method comprising: 2. The electronic evaluation circuit, consisting of a digital-to-analog converter and a controller or integrator (15), a trigger (16), a monoflop (17), and / or an AND gate (18), may have an amplitude limit exceeded (A) and / or money specific time t _k, the method of claim 1, wherein the determined based on signal characteristics at the output of the selective amplifier (14). 3. The method according to claim 1, wherein the authenticity classification is performed by an electronic evaluation circuit by setting an amplitude limit (A) for the authenticity of the currency to be matched. 4. Classification of different banknotes and / or classified documents is performed by the electronic evaluation circuit, preferably by means of a controller, by setting a currency-specific time (t _k ), the times t ₁ ..t _k−1 , t _k the method of claim 1 or 2, characterized in that the inspection object having a _{+1 ..t n} are processed. 5. According to the collation of the authenticity Method according to one or more of the preceding claims, characterized in that the collation to be added is executed in money having a time equal to the time (t _k). 6. A special evaluation unit, preferably one or more controllers, generates device-specific signals by means of time comparisons and / or voltage comparisons for transferring individual items into special slots or stacking containers. A method according to one or more of the preceding claims. 7. In a direction intersecting the feed direction of the test object, the antenna and / or the electrodes are parallel to a predetermined lateral action of the test object, and are located on the front side or the rear side where the test object is facing upward, and Claim, characterized in that they are of longitudinal length, regardless of whether they pass through, and the security strip or wire sweeps the antenna and / or the electrodes in contact therewith at any given gap. The method according to one or more of the paragraphs. 8. A method according to one or more of the preceding claims, wherein the additional matching is performed as a result of being coupled to the signal of the evaluation circuit by an AND gate without the need for software modification of the predetermined processing unit. 9. 9. Apparatus for collating confidential documents with conductive assurance strips, thin lines or two-dimensionally structured assurance material and performing the method according to one or more of claims 1 to 8, comprising: Forming one or more test areas in one or more planes in the vicinity of the optical and / or magnetic sensors and / or format sensors that activate the test sensor array therein; A plurality of sensors coupling the antenna with energy in a high frequency range across the test object, depending on the geometry and / or conductivity of the test object, one or more of the antennas being the same Transmits the energy transmitted at the phase position or at a different phase position to the intermediate selectivity amplifier (14), for example in banknotes, to disturb the disturbing energy and to block the main conductivity A phase controller connected to the output of the selective amplifier (14), a special filter for blocking disturbance and external energy, and an analog-to-digital converter, controller or integrator (15), a trigger. (16), an evaluation unit composed of a monoflop controller (17), and / or an AND gate (18), and a brush and / or a suppression member and / or a feed belt (10), a roller, Apparatus characterized in that by means of clamps and the like, the test object is lined up for sweeping by sensors in undetermined positioning without predetermined contact and at a predetermined speed. Ten. The sensor serving as a transmitting or receiving antenna is characterized in that it is configured as a strip sensor (8; 9) in one plane or in two planes arranged oppositely and / or symmetrically. An apparatus according to claim 9. 11． 10. The strip sensor (8; 9) comprises cavities and / or apertures and / or windows, or such is arranged adjacent to the strip sensor (8; 9). Or the device according to 10. 12． 12. The apparatus according to claim 9, wherein the sensors in the inspection unit are arranged symmetrically with respect to the inspection area and / or security strips, wires and / or tapes of the object to be matched. 13. 9. Apparatus for matching a confidential document having conductive assurance strips, wires or two-dimensionally structured assurance material and performing the method according to one or more of claims 1 to 8, comprising a test sensor. A plurality of transmitting antennas (A2, A3, B2.1..B2.n) and a plurality of receiving antennas (A1, B1.1..B1.n) forming an array form a plurality of conductive regions insulated from each other. Provided so that the assurance strips with conductivity can be aligned so that the test sensor array (54) is transferred parallel to the arcuate derivative (56) or the feed roller (55) And aligned perpendicular to the direction of the longest length of the security strip, and perpendicular to the feed direction of the confidential document being matched, to transfer low or high frequency energy. Two transmitting antennas (A2, A 3), and one or more oppositely arranged receiving antennas (A1), and between them several transmitting antennas (B2.1..B2. n) and several receiving antennas (B1.1..B1.n) parallel to the transmitting antennas (B2.1..B2.n), and thereby nearby transmitting antennas (B2.i..b2.n). I + 1) and the corresponding receiving antenna (B1.I, B1.I + 1) are at a predetermined distance, rather than the distance between the transmitting antenna (B2.I) and the corresponding receiving antenna (B1.I). The minimum distance between the corresponding receiving antenna (B1.I) and the transmitting antenna (B2.I) is the first distance between one of the transmitting antennas (A2, A3) and the receiving antenna (A1). An apparatus characterized by the following. 14. Some transmitting antennas (A2, A3, B2.1..B2.n) and receiving antennas (A1, B1.1 .. B1.n) are arranged over the full width of the feed path for confidential documents. 14. The device according to claim 13, wherein: 15． The transmitting antennas (A2, A3, B2.1..B2.n) and the receiving antennas (A1, B1.1..B1.n) are arranged parallel to each other in a plane adjacent to each other, and the authenticity verification of confidential documents can be performed. Apparatus according to claim 13 or 14, characterized in that it is performed independently of the sides and edges with respect to the edges of two parallel confidential documents. 16． Receiving antennas (B1.1..B1.n) and transmitting antennas (B2.1..B2.n) shifted in parallel and / or laterally, ensure that each assurance element to be verified is Irrespective of the arrangement, the receiving antennas (B1.1..B1.n) and the corresponding transmitting antennas (B2.1..B2.n) are arranged in a separated gap so as to be swept. Apparatus according to one or more of claims 13 to 15. 17． The said longest side of the transmitting antenna (B2.I) and the longest side of the corresponding receiving antenna (B1.I) correspond to the width of the conductive mark of the guarantee strip, wherein An apparatus according to one or more of the above. 18． By means of rectifiers (45, 48..50) and selective amplifiers (46, 51..53) operable or software controlled switch and setting elements, in particular of selective amplifiers (46, 51..53) Apparatus according to one or more of the preceding claims 13 to 17, characterized in that a microcontroller (47) is arranged in which the output signals are combined or logically joined. 19. By means of rectifiers (45,48..50) and selective amplifiers (46,51..53) operable or software controlled switch and setting elements, especially the different types and types of confidential documents and the degree of fraying Apparatus according to one or more of the preceding claims, characterized in that the microcontroller (47) is arranged such that changes between are performed without changing the arrangement of the sensors. 20. The minimum distance between the two transmitting antennas (B2.I) in a row is greater than or equal to the minimum distance between the two conductive and insulated markings on the security strip, and the element change is based on the antenna (A3 ) Are arranged to be used as either transmitting or receiving antennas, depending on the feed of the confidential documents to be matched. apparatus. twenty one. The software or manually controlled switch element is characterized in that one or more transmitting antennas (B2.I) and corresponding receiving antennas (B1.I) are selectively activated or deactivated. Apparatus according to one or more of claims 13 to 20.