JP2002528781A - Valuable or confidential material verification system - Google Patents

Abstract

(57) [Summary] Provide a system for verifying valuable or confidential materials. On this valuable or confidential material, one or more confidential parts are located or embedded. These secrets are incorporated into the printing ink and / or the substrate as a small amount of fluorescent or luminescent material that provides a contrast.

Description

DETAILED DESCRIPTION OF THE INVENTION

The present invention relates to a valuable or confidential substance verification system and a valuable or confidential substance verified by the verification system.

Here, the valuable or confidential material is, for example, a bill or an identification card. In the current technology, one or a plurality of confidential parts are placed on the valuable or confidential material or embedded therein. Or have been.

[0003] The present invention is based on the need to quickly prove that a document is authentic. However, today, authenticity evaluation by machine requires relatively long processing. For example, as a known technique, there is a method of adding a confidential document using a magnetic piece as a confidential section and measuring the magnetism. There is also a method of attaching a hologram or the like to a confidential document and detecting the hologram or a component thereof by measuring the diffraction of light. In addition, magnetic dyes can be added to confidential documents to measure their respective magnetisms, or to add a safety thread to valuable or confidential materials, and to determine the conductivity, components, print patterns, or other features of the safety thread. Methods for detecting are also known.

When using a machine for optical verification of secure documents, the cycle time for processing secure documents is at least about 20 milliseconds, which translates to a processing speed of 50 sheets per second. Such a long verification time is not suitable for processing a large number of documents.

[0005] In particular, a method for exciting a fluorescent printing ink for verifying valuable and confidential materials is known. Light irradiation is measured using a video camera (spatial resolution) or a photocathode (non-spatial resolution). I do.

[0006] These conventional verification systems have the disadvantage that their sensitivity is not very good. Also, the spatial resolution is not always high and the switching time is not short.

Therefore, an object of the present invention is to improve the performance of a system for verifying valuable or confidential materials, and to perform high-speed optical recognition of confidential parts placed on valuable or confidential materials.
The goal is to achieve high spatial resolution and short switching times, and to significantly increase sensitivity.

The above object of the present invention is achieved by the technical disclosure of claim 1.

According to a feature of the invention, employing a multi-channel amplifier (MCPV detector),
High-speed (validation of a large number of documents per unit time or excitation pulse) with high sensitivity (the minimum density of the secret part is enough) and high resolution (recognition of even the finest structure of the secret part). Verification in a short time after detection).

The multi-channel amplifier used in this case is further advantageous in that it is small and can be operated in direct contact with the document. The microchannel plate can replace the image forming optical device. In this way, the image information can be read directly electronically. The device manufactured here is complicated and cannot be easily imitated.

According to the disclosure of the first aspect, the pattern of the confidential portion placed on the valuable or confidential material can be detected with high spatial resolution in a short time.

The spatial resolution of such a multi-channel amplifier is determined by the storage density of the channel. These channel spacings are in the range of 10 to 20 μm, and can measure very fine parts of security patterns placed on valuables or secrets.

In addition to realizing high spatial resolution, the image sensor of the present invention, unlike other conventional image sensors, has a very short switching time due to the increase in electron avalanche in the channel due to the high applied voltage. For this reason, it is possible to quickly and sequentially take out images of a plurality of weakly light-sensitive confidential patterns or to measure the luminance density distribution at very short intervals in which the luminance density distribution is precisely determined.

For example, a multi-channel image amplifier can measure the light emission of an object several nanoseconds after excitation of the object in pulses of several nanoseconds in duration. If the decay time of the light emission of the object is also in the range of a few nanoseconds, the object can only be detected by the detector according to the invention. Only the detector according to the invention can detect a weak radiation signal following a strong excitation signal within a very short time, and can detect such a radiation signal with high spatial resolution.

The invention, together with a verification system, relates to valuables and confidential materials having a confidential part.

In the valuable and confidential materials according to the present invention, one or more confidential portions are placed on the valuable and confidential materials, and the confidential portions are formed of a small amount of fluorescent or luminescent substance that forms a contrast. In addition to printing inks and / or substances. In this way, absorptive luminescent distributions are formed as confidential parts on valuables and confidential materials, which can be detected and processed only by the optical multi-channel amplifier.

According to a basic concept of the present invention, a fluorescent or luminescent substance that forms a contrast is used as a secret that can only be detected by a sensitive and high-resolution multi-channel amplifier. Sensitive areas consisting of very small amounts of material can only be measured using special equipment (ie optical multichannel amplifiers).

Therefore, the present invention is advantageous in that a very small amount of a fluorescent or luminescent substance that forms a contrast is used as a secret part, so that it becomes difficult to detect the secret part itself. These substances can only be detected by special measuring instruments. Furthermore, the optical multi-channel amplifier can not only detect small-density secrets, but also simultaneously detect, for example, the distribution of secrets in the area of valuables and secrets. Further, a detection interval shorter than the interval of the excitation time is maintained, and the detection operation can be performed only by a detector having a correspondingly shorter response time.

The optical multi-channel amplifier has such a high sensitivity that the concentration and / or contrast of the luminescent substance can be so low that they cannot be detected by other detectors or by visual inspection. Further, since the position of the luminescent ink is not known, even if the confidential document is spectrally analyzed using a photomultiplier having high sensitivity, the possibility of signal detection is low. Even if the position is accidentally hit, the spatial distribution of the signal is almost impossible to measure with a resolution that corresponds to an optical multi-channel amplifier. Therefore, it is almost impossible to imitate such a luminance distribution.

With the high sensitivity of the optical multi-channel amplifier, weak non-linear photoelectric effects can be detected as confidential.

The sensitive wavelength sensitivity of the optical multi-channel amplifier due to the physical properties of the photocathode can be advantageously used to distinguish it from background light.

With the high spatial resolution of the optical multi-channel amplifier, the position of weak light emitting particles is also 20 μm.
m or more. For example, the distribution of the electrostatically dispersed fluorescent or luminescent particles can be measured and stored on the same document as an identification file. The identification data is compared with the light emission pattern to verify whether or not the object is authentic. In such documents, a high level of confidentiality can be maintained because it is very unlikely that a counterfeiter can measure the dispersion of very weak light-emitting particles. Moreover, for example, it is considered almost impossible to imitate the arrangement of about 100 to 10,000 light emitting points. In such systems, the use of laminated foils is particularly suitable because the light emitting particles can be assimilated into the foil and protected in the foil.

Systems based on optical multi-channel amplifiers also take advantage of the short switching times of such image amplifiers to provide a security layer for anti-counterfeiting. The light emitting material can be selected such that the excitation requires a very high peak power (such as a nanosecond laser) and the light emission occurs within a few nanoseconds after the excitation and near the wavelength of the excitation. Thereafter, the optical multi-channel amplifier is started at the end of the excitation pulse to image the light distribution. Detectors that cannot be started with such accurate gate times are easily saturated with high excitation intensities so that no signal can be detected even if an attempt is made to measure at the correct wavelength and at the correct position.

The optical multi-channel amplifier is similarly activated by other excitation mechanisms (such as an electric field in the case of electroluminescence).

The short switching times of optical multi-channel amplifiers are useful for very high-speed value verification. Such an image amplifier has a short shutter speed so that images can be obtained from each valuable document passing through the detector even at high speeds.

The optical multi-channel amplifier can also inspect the entirety of a plurality of confidential documents with only a single image acquisition by verifying the luminance distribution at the edges of the plurality of stacked confidential documents.

Optical multi-channel amplifiers can also be read directly electronically using anode strips, grid anodes, and charge measurements. As electronic processing and evaluation of image data has progressed rapidly, more powerful and faster image processing algorithms are available.

The electrostatically imaged image amplifier can electronically control the magnification of the image.

An optical multi-channel amplifier can directly convert an electron beam, an ion beam, and X-rays into an amplified visible image without using a photocathode. To give an example, a weak contrast in the X-ray region can be measured.

A typical security image field extends several square centimeters. As the simplest example, an optical multi-channel amplifier using a photocathode can directly contact the document to be verified without having to use imaging optics.

Optical multi-channel amplifiers are small, consume little power, and do not wear out.

The manufacturing process of an optical multi-channel amplifier is very complicated. Specially designed multi-channel amplifiers are easy to protect against counterfeiting. In addition, in many embodiments of the present invention, even real sensors are useless to counterfeiters because sensitive areas (such as electrostatically dispersed fluorescent particles) cannot be easily mimicked.

Optical multi-channel amplifiers can also be used to detect features in existing confidential documents and / or to inspect material features and detect evidence of forgery (such as paper or ink differences).

In summary, the advantages of the present invention using an optical multi-channel amplifier are as follows.

Optical multi-channel amplifiers are ideal as sensors for low light radiation dispersion on confidential documents. The characteristics that are the reason are shown below. 1) Very high sensitivity (detection of photons is possible).

2) Very high spatial resolution (up to 10,000 dpi).

3) Very short switching times (several nanoseconds range).

4) Wavelength selected from the appropriate photocathode and the function of the photoelectric effect (“daylight blind” sensor).

5) Direct detection of electron and ion beams together with X-rays is possible.

6) Sensor area (several square centimeters) corresponding to the characteristic size of the secret part
.

7) The image forming area can be enlarged electronically.

8) Electronic reading and processing of luminance distribution is possible without intermediate steps.

9) Small size and low power consumption.

10) Complex sensor manufacturing technology that is only available to a small number of manufacturers.

11) Suitable as a "black box" sensor (self-destructs when the box is manipulated by touching the vacuum seal or operating at high pressure, etc.). Hereinafter, this type of optical multi-channel amplifier is referred to as MCPBV.

An outline of the case where the above-described amplifier is used together with valuable and confidential materials having a weakly luminous confidential part will be described below.

MCPBV detects very small brightness distributions caused by changes in absorptivity, conductivity, reflectance, refractive index, diffraction rate, emissivity, etc. that vary over the area of the confidential area. Due to the high sensitivity of MCPBV, very low concentrations of contrast or photoimageable materials, weak reflections, diffraction patterns, etc., are sufficient for accurate verification.

The concentration of the contrast-forming or light-emitting substance and / or the reflection, absorption and diffraction planes (confidential parts) are reduced so that the luminance generated therefrom cannot be detected by other sensors. The low intensity of the nonlinear photoelectric effect makes it suitable as a secret part (multiple excitation processes such as two-light absorption can make the detection of such a secret part even more difficult).

Very weak intensity distributions contain coded or customized information. Only MCPBV can read such information because other types of detectors cannot provide a correspondingly high spatial resolution with high sensitivity.

The MCPBV is synchronized with the excitation operation so that a weak measurement signal can be distinguished from a strong excitation pulse. Other detectors cannot detect such signals.
Simple synchronization synchronized with multiple excitations is also possible.

It is also possible to use a part of the confidential document (for example, only the side edge when stacked) for verification. In this case, it is possible to verify up to several hundred confidential documents per second with a short shutter time of MCPBV.

The “daylight blind” MCPBV contacts confidential documents. Background light is effectively suppressed and no imaging optics (handheld device) is required.

MCPBV can also inspect X-ray contrast with high sensitivity and high spatial resolution without using a photographic emulsion.

The verification device uses a specially designed MCPBV with a special photocathode, channel cross-section, and other parameters (eg, a linear MCPBV array). Due to complex manufacturing techniques, these detectors cannot be used by counterfeiters (the information contained in the columns cannot be read by counterfeiters).

According to another embodiment of the present invention, a large number of documents can be verified per second because the detection time is short. For example, machine processing of up to 2000 documents per second is possible.

The content of the present invention is not limited only by the features described in each claim.
It is also defined by a combination of claims.

All features, including the abstract, disclosed herein, particularly the features shown in the drawings, are claims of the present invention, alone or in combination, having novelty over the present art. is there.

Hereinafter, the present invention will be described with reference to a plurality of embodiments shown in the drawings. Further features and advantages of the invention will also be apparent from the drawings and the description. FIG. 1 shows different confidential parts 2, 3 arranged in any manner on a confidential document 1.
Further, one or more confidential pieces 6 and / or one or more characters (patterns) 7 are arranged on the confidential document 1.

This type of security section 2, 3 is distributed and includes a plurality of pixels 4, 5 representing the regular or irregular distribution of the security section 2, 3.

The confidential document 1 is a bank note, an identification card, or the like, and the confidential parts 2 and 3 and / or the confidential pieces 6 and the characters 7 are embedded in the confidential document 1 even if they are embedded therein. It may be mounted.

The inspection of the confidential part provided for the verification of the confidential document 1 will be described in detail below.

The present invention provides a so-called micro-channel image amplifier 8, schematically shown in FIG. The confidential sections 2, 3, and 6 placed on the confidential document 1 emit a weak signal when excited, and this signal is transmitted to the microchannel image amplifier 8 in the direction of arrow 11-3. This weak signal is measured by a special test device. Secret Department 2, 3,
6 is excited by an excitation light source 9 which irradiates the confidential document 1 in the direction of arrow 10, for example.

Here, the type and arrangement of the excitation light source 9 for the confidential document can be arbitrarily changed.
The excitation light source 9 may be arranged on the confidential document side or on the microchannel image amplifier side. The excitation light source 9 is directed to the confidential document 1, and the signal is transmitted to the confidential document 1.
To the microchannel image amplifier 8 in the opposite direction. The excitation light source can also be located below the secure document, in which case the emitted light will pass through the secure document.

The excitation light source 9 includes a plurality of different excitation mechanisms such as excitation by an electron beam, laser beam, visible light, X-ray, or ion beam, and excitation by an alternating magnetic field.

As in the case of ultraviolet irradiation, thermal excitation (infrared irradiation) is also applicable.

[0066] Low brightness transmitted through the valuables is detected during transmission.

The confidential part is composed of a small amount of a fluorescent substance or a luminescent substance which forms a contrast contained in the printing ink or the base.

In addition, other excitation mechanisms can be applied, such as bioluminescent or chemiluminescent systems, which are very difficult to detect, or drugs using fluorescent markers.

FIG. 3 shows details of the basic structure of the microchannel image amplifier.

First, there is a window in the vacuum housing 14 covered by a photocathode. For simplicity,
In the figure, the photocathode 15 is located inside the housing 14. The photon flux 19 illuminates the photocathode 15 from the direction of arrow 18. The photocathode 15 emits electrons 35 due to the photon flux 19, and these electrons 35 are accelerated in the direction of the arrow 36 toward the microchannel plate 16. FIG. 4 shows the structure of the microchannel plate 16. The microchannel plate 16 is composed of hollow channels 20, and arrows 21 from inner walls 22 and 23.
Are emitted in the direction of and proceed zigzag, and as a result, secondary electrons are emitted from the coating on the inner walls 22 and 23. These secondary electrons are converted into microchannels 2 in the form of an avalanche 24.
It is emitted from 0 and goes to the luminescent screen 17. In the light-emitting screen 17, the electron flux is converted into divergent light having the corresponding brightness, and the process proceeds further. As a device for evaluating luminance, for example, there is a CCD or the like. Also, the electron beam can be directly measured without installing the light-emitting screen 17.

The above functions can be performed by a general image forming system.

FIG. 5 shows an excitation of the type described above with a response pulse. As shown, the secret document is irradiated with a very short duration excitation pulse 25 of a few nanoseconds to excite the secret located thereon. The security units 2, 3, 6 respond to the corresponding response pulse 26 delayed by Δt.

As shown in FIG. 5, the evaluation time 27 in the range of only a few nanoseconds is relatively short,
Since there are very few devices that can perform verification in such a short time, they are particularly suitable for forgery protection against valuable or confidential materials.

Most known detectors cannot discriminate between the signal from the excitation pulse 25 and the signal from the response pulse 26, that is, cannot perform verification within the evaluation time 27.

Thus, the verification method according to the invention provides a very short excitation pulse 2 in nanoseconds.
5 based on the excitation at 5. If a long excitation pulse is used, the subsequent response pulse is obscured by the excitation pulse 25 and cannot be measured.

The verification method of the present invention also includes an excitation light source 9 that can generate a short excitation pulse as described above, and a verification unit (a microchannel image amplifier 8) that can perform verification within a short evaluation time 27. And to use.

FIG. 6 shows another embodiment of a confidential document under more strict confidentiality conditions.

A large number of confidential sections 2 and 3 are arranged on the encoding surface 28 defined by the registration mark 30 and emit light when excited. The above-described measuring unit determines the coordinates of the light-emitting and light-emitting confidential parts. In addition to determining the coordinates (position) of the confidential part, other features of the confidential part, such as individual brightness, distribution status, color, and size, are also read out on the confidential document 1.

These read characteristics are written in a read field 29 located on the confidential document 1, for example.

In order to verify the confidential document 1, the confidential document 1 is excited by the excitation light source 9, reads out the features of the confidential parts 2, 3 in the coding plane 28, and reads the information stored in the readout field 29 with the information stored in the readout field 29. Compare. As described above, it is possible to provide a quickly verified valuable resource without fear of forgery.

The countermeasures against forgery can be further enhanced by a large number of confidential parts 2 and 3 distributed on the encoding surface 28 in a predetermined distribution pattern.

In this way, only a specific confidential document is encoded with a precisely defined predetermined code, and it is possible to identify a specific confidential document from the apparently identical confidential documents. Banknotes paid as ransoms can be identified at a later date.

Further, the excitation light source 9 can be omitted. The confidential units 2, 3, and 6 described above also
It can also be applied as a luminous body. This type of illuminant is a sensitive part 2 in the form of a self-emitting source.
, 3 and 6.

FIG. 7 shows another embodiment of the excitation mechanism for verification. In this embodiment, an ionizing radiation source 31 performs the excitation. Any number of barriers having any configuration and opaque to emitted light are disposed on the confidential document 1. These barriers 34 penetrate only the specific region 37 in the direction of the arrow 38 in the X-rays 32 irradiating the confidential document 1 and block the remaining regions. With this configuration, the radiation light unique to the confidential document 1 reaches the micro channel plate 16 installed in the housing together with the luminescent screen 17.

The feature described with reference to FIG. 7 is applicable even when the electron beam source is selected instead of the ionizing radiation source 31 as long as the confidential document 1 is not included in the housing 33. To introduce the secure document 1 into the housing, the housing is exposed to an inert gas.

With such a configuration, the confidential document 1 can be quickly introduced into the housing and taken out.

The inert gas activates the movement of electrons in the housing. Hereinafter, the non-linear photoelectric effect according to the method of the present invention will be described.

In this type of excitation mechanism, the secrets 2, 3 are excited at the first frequency,
It emits light in another frequency range. Here, the secondary radiation is measured by the microchannel image amplifier of the present invention.

Such non-linear effects are generally very weak and are therefore particularly suitable for measurements with the microchannel image amplifier of the present invention.

Furthermore, the main beam can be filtered or invisible from the photoelectrode by properly designing the photocathode. That is, only the nonlinear optical signal is evaluated.

[Brief description of the drawings]

FIG. 1 is a top view of a first embodiment of a valuable or confidential material.

FIG. 2 is a schematic side view of the verification device.

FIG. 3 is a schematic sectional view of a microchannel image amplifier.

FIG. 4 is an enlarged view of the channels of the microchannel image amplifier, showing the excitation mechanism in the microchannel plate.

FIG. 5 is a diagram illustrating a comparison between an excitation pulse and a response pulse during verification of a confidential document.

FIG. 6 is a top view of a confidential document under stricter confidentiality conditions.

FIG. 7 is a diagram showing another embodiment of the microchannel image amplifier in comparison with FIG. 3;

[Explanation of symbols]

 Reference Signs List 1 confidential document 2 confidential part 3 confidential part 4 pixel 5 pixel 6 confidential piece 7 character 8 microchannel image amplifier 9 excitation light source 10 directional arrow 11 directional arrow 12 directional arrow 13 directional arrow 14 vacuum housing 15 photocathode 16 microchannel plate 17 fluorescence Screen 18 directional arrow 19 photon 20 channel 21 directional arrow 22 internal space 23 internal space 24 electron avalanche 25 excitation pulse 26 response pulse 27 evaluation time 28 coding surface 29 readout field 30 registration mark 31 radiation source 32 X-ray 33 housing 34 barrier 35 Electron 36 Direction arrow 37 Specific area 38 Direction arrow

[Procedural Amendment] Submission of translation of Article 34 Amendment of the Patent Cooperation Treaty

[Submission date] December 21, 1999 (December 21, 1999)

[Procedure amendment 1]

[Document name to be amended] Statement

[Correction target item name] Full text

[Correction method] Change

[Correction contents]

[Title of the Invention] Valuable or confidential substance verification system

[Claims]

DETAILED DESCRIPTION OF THE INVENTION

The present invention relates to a valuable or confidential substance verification system and a valuable or confidential substance verified by the verification system.

Here, the valuable or confidential material is, for example, a bill or an identification card. In the current technology, one or a plurality of confidential parts are placed on the valuable or confidential material or embedded therein. Or have been.

[0003] The present invention is based on the need to quickly prove that a document is authentic. However, today, authenticity evaluation by machine requires relatively long processing. For example, as a known technique, there is a method of adding a confidential document using a magnetic piece as a confidential section and measuring the magnetism. There is also a method of attaching a hologram or the like to a confidential document and detecting the hologram or a component thereof by measuring the diffraction of light. In addition, magnetic dyes can be added to confidential documents to measure their respective magnetisms, or to add a safety thread to valuable or confidential materials, and to determine the conductivity, components, print patterns, or other features of the safety thread. Methods for detecting are also known.

When using a machine for optical verification of secure documents, the cycle time for processing secure documents is at least about 20 milliseconds, which translates to a processing speed of 50 sheets per second. Such a long verification time is not suitable for processing a large number of documents.

[0005] In particular, a method for exciting a fluorescent printing ink for verifying valuable and confidential materials is known. Light irradiation is measured using a video camera (spatial resolution) or a photocathode (non-spatial resolution). I do.

[0006] These conventional verification systems have the disadvantage that their sensitivity is not very good. Also, the spatial resolution is not always high and the switching time is not short.

[0007] EP 0537513 discloses an apparatus for validating bills using a pair of superposed plates defining a space for receiving bills for inspection . In this case, banknote is first irradiated with the infrared spectrum and the red and green light emitting diodes.

These diodes are sequentially pulsed so that the bill is always illuminated in only one color or infrared spectral range. Are on both sides to the diode arrangement of the bill, reflected light from the bill is one that, is transparently light passing through the paper money on the other hand, are I Do to be received by a sensor in the form of a single linear CCD array . The CCD array converts the light from the bill into electric signals and transmits the signals it to the processing unit.

[0009] However, this device for verifying banknotes, on the other hand, has only a relatively low spatial resolution, which limits the pattern of the confidential part to a minimum. On the other hand, this device can only obtain relatively small amplification constants and consequently can detect only relatively strong light emission above a certain threshold value for sensitive parts of banknotes . A relatively long switching time also limits the amount of passage of the bills and reduces the throughput of the bill validator .

[0010] US Patent No. 4,780,395 discloses a microchannel plate that operates substantially as a multi-channel amplifier . The microchannel plate has a photosensitive glass substrate layer, it is arranged at a distance from one another, comprising a plurality of microchannels extending I suited the other end surface from the one end face of the plate. In this configuration, the surface area of the microchannel is formed for emission of secondary electrons.

[0011] Acceleration electrodes are arranged on both sides of the photosensitive glass substrate so that the photosensitive glass substrate is in partial electrical contact with the secondary emission surface. That is, the cathode, through the electron emission, converts the light photons into emission electron. These electrons pass through the microchannels of the microchannel amplifier unit, where it is accelerated are multiplexed. The multiplexed secondary electrons exit from the end face of the substrate opposite the cathode and are taken in by the anode to form a screen for forming a visible image .

[0012] US Patent No. 4,146,792 discloses a confidential document and an apparatus for verifying the confidential document . The confidential document, a fluorescent substance, all or a point Oh Rui paper contains several points. These fluorescent substances, after excitation, performs radiation in the visible ultraviolet, or infrared-ray spectrum region. These fluorescent substance, or adhere to confidential documents in the form of printing inks, or may be immersed a confidential document to the fluorescent substance.

The security document inspection apparatus includes an excitation light source, and an array of lenses and photoelectric cells for receiving light emitted from the security portion of the document . Also in the test equipment of this confidential document, relatively low spatial resolution, the amplification factor is relatively small, there is a problem that a relatively longer switching time.

Therefore, an object of the present invention is to improve the performance of a system for verifying valuable or confidential materials, and to perform high-speed optical recognition of confidential parts placed on valuable or confidential materials.
The goal is to achieve high spatial resolution and short switching times, and to significantly increase sensitivity.

The above object of the present invention is achieved by the technical disclosure of claim 1.

According to a feature of the invention, employing a multi-channel amplifier (MCPV detector),
High-speed (validation of a large number of documents per unit time or excitation pulse) with high sensitivity (the minimum density of the secret part is enough) and high resolution (recognition of even the finest structure of the secret part). Verification in a short time after detection).

The multi-channel amplifier used in this case is further advantageous in that it is small and can be operated in direct contact with the document. The microchannel plate can replace the image forming optical device. In this way, the image information can be read directly electronically. The device manufactured here is complicated and cannot be easily imitated.

According to the disclosure of the first aspect, the pattern of the confidential portion placed on the valuable or confidential material can be detected in a short time with high spatial resolution.

The spatial resolution of such a multi-channel amplifier is determined by the storage density of the channel. These channel spacings are in the range of 10 to 20 μm, and can measure very fine parts of security patterns placed on valuables or secrets.

In addition to realizing high spatial resolution, the image sensor of the present invention, unlike other conventional image sensors, has a very short switching time due to an increase in avalanche in the channel due to the high applied voltage. For this reason, it is possible to quickly and sequentially take out images of a plurality of weakly light-sensitive confidential patterns or to measure the luminance density distribution at very short intervals in which the luminance density distribution is precisely determined.

For example, a multi-channel image amplifier can measure the light emission of an object a few nanoseconds after excitation of the object in pulses of several nanoseconds in duration. If the decay time of the light emission of the object is also in the range of a few nanoseconds, the object can only be detected by the detector according to the invention. Only the detector according to the invention can detect a weak radiation signal following a strong excitation signal within a very short time, and can detect such a radiation signal with high spatial resolution.

Together with the verification system, the invention relates to valuables and confidential materials having a confidential part.

The valuable and confidential material according to the present invention has one or more confidential parts mounted on the valuable and confidential material, and the confidential part is composed of a small amount of fluorescent or luminescent substance forming a contrast. Is added to a printing ink and / or a substrate. In this way, absorptive luminescent distributions are formed as confidential parts on valuables and confidential materials, which can be detected and processed only by the optical multi-channel amplifier.

According to a basic concept of the present invention, a fluorescent or luminescent substance that forms a contrast is used as a secret that can only be detected by a sensitive and high-resolution multi-channel amplifier. Sensitive areas consisting of very small amounts of material can only be measured using special equipment (ie optical multichannel amplifiers).

Therefore, the present invention is advantageous in that a very small amount of a fluorescent or luminescent substance that forms a contrast is used as a secret part, making it difficult to detect the secret part itself. These substances can only be detected by special measuring instruments. Furthermore, the optical multi-channel amplifier can not only detect small-density secrets, but also simultaneously detect, for example, the distribution of secrets in the area of valuables and secrets. Further, a detection interval shorter than the interval of the excitation time is maintained, and the detection operation can be performed only by a detector having a correspondingly shorter response time.

The optical multi-channel amplifier has such high sensitivity that the concentration and / or contrast of the luminescent material can be so low that they cannot be detected by other detectors or visual inspection. Further, since the position of the luminescent ink is not known, even if the confidential document is spectrally analyzed using a photomultiplier having high sensitivity, the possibility of signal detection is low. Even if the position is accidentally hit, the spatial distribution of the signal is almost impossible to measure with a resolution that corresponds to an optical multi-channel amplifier. Therefore, it is almost impossible to imitate such a luminance distribution.

With the high sensitivity of the optical multi-channel amplifier, weak non-linear photoelectric effects can be detected as confidential.

The sensitive wavelength sensitivity of the optical multi-channel amplifier due to the physical properties of the photocathode can be advantageously used to distinguish it from background light.

With the high spatial resolution of the optical multi-channel amplifier, the position of weak light emitting particles is also 20 μm.
m or more. For example, the distribution of the electrostatically dispersed fluorescent or luminescent particles can be measured and stored on the same document as an identification file. The identification data is compared with the light emission pattern to verify whether or not the object is authentic. In such documents, a high level of confidentiality can be maintained because it is very unlikely that a counterfeiter can measure the dispersion of very weak light-emitting particles. Moreover, for example, it is considered almost impossible to imitate the arrangement of about 100 to 10,000 light emitting points. In such systems, the use of laminated foils is particularly suitable because the light emitting particles can be assimilated into the foil and protected in the foil.

Systems based on optical multi-channel amplifiers also take advantage of the short switching times of such image amplifiers to provide a security layer for anti-counterfeiting. The light emitting material can be selected such that the excitation requires a very high peak power (such as a nanosecond laser) and the light emission occurs within a few nanoseconds after the excitation and near the wavelength of the excitation. Thereafter, the optical multi-channel amplifier is started at the end of the excitation pulse to image the light distribution. Detectors that cannot be started with such accurate gate times are easily saturated with high excitation intensities so that no signal can be detected even if an attempt is made to measure at the correct wavelength and at the correct position.

An optical multi-channel amplifier is similarly activated by other excitation mechanisms (such as an electric field in the case of electroluminescence).

The short switching time of the optical multi-channel amplifier is useful for very high speed value verification. Such an image amplifier has a short shutter speed so that images can be obtained from each valuable document passing through the detector even at high speeds.

The optical multi-channel amplifier can also inspect the entirety of a plurality of confidential documents with only a single image acquisition by verifying the luminance distribution at the edges of the plurality of confidential documents.

Optical multi-channel amplifiers can also be read directly electronically using anode strips, grid anodes, and charge measurements. As electronic processing and evaluation of image data has progressed rapidly, more powerful and faster image processing algorithms are available.

An electrostatically imaged image amplifier can electronically control the magnification of an image.

An optical multi-channel amplifier can directly convert an electron beam, an ion beam, and X-rays into an amplified visible image without using a photocathode. To give an example, a weak contrast in the X-ray region can be measured.

A typical security image field extends over several square centimeters. As the simplest example, an optical multi-channel amplifier using a photocathode can directly contact the document to be verified without having to use imaging optics.

The optical multi-channel amplifier is small, consumes less power, and does not wear out.

The manufacturing process of an optical multi-channel amplifier is very complicated. Specially designed multi-channel amplifiers are easy to protect against counterfeiting. In addition, in many embodiments of the present invention, even real sensors are useless to counterfeiters because sensitive areas (such as electrostatically dispersed fluorescent particles) cannot be easily mimicked.

Optical multi-channel amplifiers can also be used to detect features in existing confidential documents and / or to inspect material features and detect evidence of forgery (such as paper or ink differences).

In summary, the advantages of the present invention using an optical multi-channel amplifier are as follows.

Optical multi-channel amplifiers are ideal as sensors for low light scatter on sensitive documents. The characteristics that are the reason are shown below. 1) Very high sensitivity (detection of photons is possible).

2) Very high spatial resolution (up to 10,000 dpi).

3) Very short switching times (in the range of a few nanoseconds).

4) Wavelength selected from the appropriate photocathode and the function of the photoelectric effect (“daylight blind” sensor).

5) Direct detection of electron and ion beams as well as X-rays is possible.

6) Sensor area (several square centimeters) corresponding to the characteristic size of the secret part
.

7) The image forming area can be enlarged electronically.

8) Electronic reading and processing of luminance distribution is possible without intermediate steps.

9) Small size and low power consumption.

[0051] 10) Complex sensor manufacturing technology, available only to a small number of manufacturers.

11) Suitable as a "black box" sensor (self-destructs when the box is manipulated by touching the vacuum seal or high pressure). Hereinafter, this type of optical multi-channel amplifier is referred to as MCPBV.

An outline of the case where the above-described amplifier is used together with valuable and confidential materials having a weakly luminous confidential part will be described below.

The MCPBV detects very small brightness distributions caused by changes in absorptivity, conductivity, reflectance, refractive index, diffraction rate, emissivity, etc. that change over the area of the confidential area. Due to the high sensitivity of MCPBV, very low concentrations of contrast or photoimageable materials, weak reflections, diffraction patterns, etc., are sufficient for accurate verification.

The concentration of the contrast-forming or light-emitting substance and / or the reflection, absorption, diffraction surface (confidential part) is reduced so that the luminance generated therefrom cannot be detected by other sensors. The low intensity of the nonlinear photoelectric effect makes it suitable as a secret part (multiple excitation processes such as two-light absorption can make the detection of such a secret part even more difficult).

Very weak intensity distributions contain coded or customized information. Only MCPBV can read such information because other types of detectors cannot provide a correspondingly high spatial resolution with high sensitivity.

MCPBV is synchronized with the excitation operation so that weak measurement signals can be distinguished from strong excitation pulses. Other detectors cannot detect such signals.
Simple synchronization synchronized with multiple excitations is also possible.

It is also possible to use the confidential document for partial verification (only the side edge when stacked). In this case, it is possible to verify up to several hundred confidential documents per second with a short shutter time of MCPBV.

The “daylight blind” MCPBV contacts a confidential document. Background light is effectively suppressed and no imaging optics (handheld device) is required.

MCPBV can also inspect X-ray contrast with high sensitivity and high spatial resolution without using a photographic emulsion.

The verification device uses a specially designed MCPBV with a special photocathode, channel cross-section, and other parameters (eg, a linear MCPBV array). Due to complex manufacturing techniques, these detectors cannot be used by counterfeiters (the information contained in the columns cannot be read by counterfeiters).

According to another embodiment of the present invention, a large number of documents can be verified per second because the detection time is short. For example, machine processing of up to 2000 documents per second is possible.

The content of the present invention is not limited only by the features described in each claim.
It is also defined by a combination of claims.

All features, including the abstract, disclosed herein, particularly the features shown in the drawings, are claims of the present invention, alone or in combination, being novel in the present art. is there.

Hereinafter, the present invention will be described with reference to a plurality of embodiments shown in the drawings. Further features and advantages of the invention will also be apparent from the drawings and the description. FIG. 1 shows different confidential parts 2, 3 arranged in any manner on a confidential document 1.
Further, one or more confidential pieces 6 and / or one or more characters (patterns) 7 are arranged on the confidential document 1.

This type of security part 2, 3 is distributed and includes a plurality of pixels 4, 5 representing the regular or irregular distribution of the security part 2, 3.

The confidential document 1 is a banknote, an identification card, or the like, and the confidential parts 2 and 3 and / or the confidential pieces 6 and the characters 7 are embedded in the confidential document 1 even if they are embedded therein. It may be mounted.

The inspection of the confidential part provided for verifying the confidential document 1 will be described in detail below.

The present invention provides a so-called micro-channel image amplifier 8, schematically shown in FIG. The confidential sections 2, 3, and 6 placed on the confidential document 1 emit a weak signal when excited, and this signal is transmitted to the microchannel image amplifier 8 in the direction of arrow 11-3. This weak signal is measured by a special test device. Secret Department 2, 3,
6 is excited by an excitation light source 9 which irradiates the confidential document 1 in the direction of arrow 10, for example.

Here, the type and arrangement of the excitation light source 9 for the confidential document can be arbitrarily changed.
The excitation light source 9 may be arranged on the confidential document side or on the microchannel image amplifier side. The excitation light source 9 is directed to the confidential document 1, and the signal is transmitted to the confidential document 1.
To the microchannel image amplifier 8 in the opposite direction. The excitation light source can also be located below the secure document, in which case the emitted light will pass through the secure document.

The excitation light source 9 includes a plurality of different excitation mechanisms such as excitation by an electron beam, laser beam, visible light, X-ray, or ion beam, and excitation by an alternating magnetic field.

As with ultraviolet irradiation, thermal excitation (infrared irradiation) is also applicable.

[0073] Low brightness transmitted through the valuables is detected during transmission.

The confidential part is composed of a small amount of a fluorescent substance or a luminescent substance that forms a contrast contained in the printing ink or the substrate.

Furthermore, other excitation mechanisms can be applied, such as bioluminescence or chemiluminescence systems, which are very difficult to detect, or drugs using fluorescent markers.

FIG. 3 shows details of the basic structure of the microchannel image amplifier.

First, there is a window in the vacuum housing 14 covered by a photocathode. For simplicity,
In the figure, the photocathode 15 is located inside the housing 14. The photon flux 19 illuminates the photocathode 15 from the direction of arrow 18. The photocathode 15 emits electrons 35 due to the photon flux 19, and these electrons 35 are accelerated in the direction of the arrow 36 toward the microchannel plate 16. FIG. 4 shows the structure of the microchannel plate 16. The microchannel plate 16 is composed of hollow channels 20, and arrows 21 from inner walls 22 and 23.
Are emitted in the direction of and proceed zigzag, and as a result, secondary electrons are emitted from the coating on the inner walls 22 and 23. These secondary electrons are converted into microchannels 2 in the form of an avalanche 24.
It is emitted from 0 and goes to the luminescent screen 17. In the light-emitting screen 17, the electron flux is converted into divergent light having the corresponding brightness, and the process proceeds further. As a device for evaluating luminance, for example, there is a CCD or the like. Also, the electron beam can be directly measured without installing the light-emitting screen 17.

The above functions can be performed by a general image forming system.

FIG. 5 shows an excitation of the type described above with a response pulse. As shown, the secret document is irradiated with a very short duration excitation pulse 25 of a few nanoseconds to excite the secret located thereon. The security units 2, 3, 6 respond to the corresponding response pulse 26 delayed by Δt.

As shown in FIG. 5, the evaluation time 27 in the range of only a few nanoseconds is relatively short,
Since there are very few devices that can perform verification in such a short time, they are particularly suitable for forgery protection against valuable or confidential materials.

Most known detectors cannot discriminate between the signal from the excitation pulse 25 and the signal from the response pulse 26, that is, cannot perform verification within the evaluation time 27.

Therefore, the verification method according to the present invention provides a very short excitation pulse 2 in nanoseconds.
5 based on the excitation at 5. If a long excitation pulse is used, the subsequent response pulse is obscured by the excitation pulse 25 and cannot be measured.

The verification method of the present invention also includes an excitation light source 9 that can generate a short excitation pulse as described above, and a verification unit (a microchannel image amplifier 8) that can perform verification within a short evaluation time 27. And to use.

FIG. 6 shows another embodiment of a confidential document under more strict confidentiality conditions.

A large number of confidential parts 2, 3 are arranged on the coding surface 28 defined by the registration mark 30, and emit light when excited. The above-described measuring unit determines the coordinates of the light-emitting and light-emitting confidential parts. In addition to determining the coordinates (position) of the confidential part, other features of the confidential part, such as individual brightness, distribution status, color, and size, are also read out on the confidential document 1.

These read features are written in a read field 29 located on the confidential document 1, for example.

In order to verify the confidential document 1, the confidential document 1 is excited by the excitation light source 9, reads out the features of the confidential parts 2 and 3 in the coding plane 28, and reads the information stored in the readout field 29 with the information stored in the readout field 29. Compare. As described above, it is possible to provide a quickly verified valuable resource without fear of forgery.

The countermeasures against forgery can be further strengthened by the large number of confidential parts 2, 3 distributed on the encoding surface 28 in a predetermined distribution pattern.

In this way, only a specific confidential document is encoded with a precisely defined predetermined code, and it is possible to identify a specific confidential document from the apparently identical confidential documents. Banknotes paid as ransoms can be identified at a later date.

The excitation light source 9 can be omitted. The confidential units 2, 3, and 6 described above also
It can also be applied as a luminous body. This type of illuminant is a sensitive part 2 in the form of a self-emitting source.
, 3 and 6.

FIG. 7 shows another embodiment of the excitation mechanism for verification. In this embodiment, an ionizing radiation source 31 performs the excitation. Any number of barriers having any configuration and opaque to emitted light are disposed on the confidential document 1. These barriers 34 penetrate only the specific region 37 in the direction of the arrow 38 in the X-rays 32 irradiating the confidential document 1 and block the remaining regions. With this configuration, the radiation light unique to the confidential document 1 reaches the micro channel plate 16 installed in the housing together with the luminescent screen 17.

The features described with reference to FIG. 7 are applicable even when the electron beam source is selected instead of the ionizing radiation source 31 as long as the confidential document 1 is not included in the housing 33. To introduce the secure document 1 into the housing, the housing is exposed to an inert gas.

With such a configuration, the confidential document 1 can be quickly introduced into the housing and taken out.

The inert gas activates the movement of electrons in the housing. Hereinafter, the non-linear photoelectric effect according to the method of the present invention will be described.

In this type of excitation mechanism, the secrets 2, 3 are excited at the first frequency,
It emits light in another frequency range. Here, the secondary radiation is measured by the microchannel image amplifier of the present invention.

Such non-linear effects are generally very weak and are therefore particularly suitable for measurements with the microchannel image amplifier of the present invention.

Furthermore, the main beam can be filtered or invisible from the photoelectrode by properly designing the photocathode. That is, only the nonlinear optical signal is evaluated.

[Brief description of the drawings]

FIG. 1 is a top view of a first embodiment of a valuable or confidential material.

FIG. 2 is a schematic side view of the verification device.

FIG. 3 is a schematic sectional view of a microchannel image amplifier.

FIG. 4 is an enlarged view of the channels of the microchannel image amplifier, showing the excitation mechanism in the microchannel plate.

FIG. 5 is a diagram illustrating a comparison between an excitation pulse and a response pulse during verification of a confidential document.

FIG. 6 is a top view of a confidential document under stricter confidentiality conditions.

FIG. 7 is a diagram showing another embodiment of the microchannel image amplifier in comparison with FIG. 3;

DESCRIPTION OF SYMBOLS 1 confidential document 2 confidential part 3 confidential part 4 pixel 5 pixel 6 confidential piece 7 character 8 microchannel image amplifier 9 excitation light source 10 directional arrow 11 directional arrow 12 directional arrow 13 directional arrow 14 vacuum housing 15 photocathode 16 Microchannel plate 17 Fluorescent screen 18 Directional arrow 19 Photon 20 Channel 21 Directional arrow 22 Internal space 23 Internal space 24 Electron avalanche 25 Excitation pulse 26 Response pulse 27 Evaluation time 28 Coding surface 29 Readout field 30 Registration mark 31 Radiation light source 32 X-ray 33 Housing 34 Barrier 35 Electron 36 Direction arrow 37 Specific area 38 Direction arrow

──────────────────────────────────────────────────続 き Continuation of the front page (72) Inventor Gutmann, Loland Germany 12349 Berlin, Shuttlese 621/18 F-term (reference) 3E041 AA03 BA09 BB04 BC01 BC03 EA03 5B072 AA01 CC33 DD22 MM09 5C022 AA01 AA15 AB68 AC42

Claims (19)

[Claims] 1. An optical image forming apparatus comprising: one or a plurality of confidential portions each comprising a weak light-emitting object arranged in a predetermined pattern and having a predetermined spectral characteristic; In a confidential matter verification system, the optical image forming apparatus is a multi-channel amplifier (MCBV). 2. The verification system according to claim 1, wherein the multi-channel amplifier has a spatial resolution determined by a storage density of the channel, which is in a range of about 10 to 20 μm. 3. The verification system according to claim 2, wherein an input of the electronic camera is arranged at an output of the multi-channel amplifier. 4. An electronic camera according to claim 3, wherein the output of the multi-channel amplifier is in direct photoconductive connection with the photocathode of the electronic camera in an image field of 1 to 3 cm 2 of a valuable or confidential document. Verification system. 5. A valuable and confidential material in which one or more confidential parts are arranged or buried in the verification system according to claim 1, wherein the confidential part has a small amount of fluorescent light forming a contrast. Alternatively, a luminescent substance is used as a printing ink and / or
Or a valuable or confidential substance formed by being mixed with a substrate. 6. The valuable and confidential material according to claim 5, wherein the confidential part is distributed in a predetermined area. 7. The valuable and confidential material according to claim 5, wherein a reference surface is defined by one or a plurality of registration marks. 8. The valuable and confidential material according to claim 7, further comprising a read field including a checksum for the reference plane. 9. The valuable and confidential material according to claim 1, wherein the confidential portion is formed as a secondary light source marking requiring excitation. 10. The valuable and confidential material according to claim 9, wherein a response time of the confidential unit is very short. 11. The valuable and confidential material according to claim 9, wherein the confidential part requires a large amount of excitation energy. 12. The valuable and confidential material according to claim 9, wherein the confidential unit generates a very short response signal. 13. The valuable and confidential material according to claim 9, wherein the response signal is located in a frequency region different from a frequency of an excitation signal. 14. The valuable and confidential matter according to claim 1, wherein at least one of the confidential parts is arranged at a margin and / or an edge of the confidential document. object. 15. A method for evaluating and inspecting valuable and confidential substances according to claim 1, wherein an optical multi-channel amplifier is used. 16. The method according to claim 15, wherein the parallel evaluation and inspection of a plurality of valuables and secrets are performed simultaneously. 17. The method according to claim 15, wherein the optical multi-channel amplifier has a sensor area corresponding to the size of up to three secret parts. 18. The method according to claim 15, wherein the optical multi-channel amplifier has high sensitivity and high resolution, and has a short switching time. 19. The method according to claim 1, wherein the optical multi-channel amplifier can be tuned to a predetermined wavelength by selecting an appropriate photocathode.