WO2009071673A1 - Method for generating a security code for a matrix printing data memory - Google Patents

Abstract

Method for generating a security code for an optically readable matrix printing data memory which has a high data density and is applied to an object or printing material with the aid of a multistage printing process, characterized in that the individuality of at least one stage of the printing process is measured and compared with the desired values and a security code is calculated therefrom and is stored, and an object having a colour matrix printing data memory which has a security code and is applied in a multistage process.

Description

 A method for generating a security code for a raster print data storage device

The invention relates to a method for generating a security code for a raster print data storage as well as an article with color raster print data storage according to the preambles of claims 1 and 6.

DE 103 45 669 A1 describes for the first time a data carrier with copy protection and a method for generating a security code on the basis of a locally random structural component of the carrier material. When the encoded data is applied to the data carrier, a modulating proportion that varies, as it were, from data carrier to data carrier, which is used as an individual security code for the detection of a copy, also arises to some extent. In the case of legal copies, this individual security code (possibly encrypted) is stored on a database or additionally on the data medium.

DE 10 2004 036 809 A1 and WO 2006/103037 A1 describe a raster print data memory which is particularly suitable for implementing the invention in DE 103 45 669 A1 in the case of printed two-dimensional data memories (also often referred to as 2D matrix codes). The print grid is designed in such a way that the data memory remains readable even at very high resolution printing, ie at very high data densities. For this purpose, DE 10 2004 036 809 A1 describes special pressure symbols in which the printing ink can run in a targeted manner without destroying the readability. In a mass production of data storage, this is of particular importance, since the amount of ink application can never be kept exactly constant. To increase the data density, the print symbols of the raster print data memory can encode additional information due to the use of different colors. DE102005013962 A1 describes the use of the technology for producing counterfeit-protected documents. The goals are a simple low-cost production and the possibility of verification with simple flatbed scanners. The object of cost-effective production is achieved in that the, according to DE 103 45 669 A1 required, detection of the individuality of the printing is achieved by producing a special document paper. The document paper serves as a cheap, mass-produced semi-finished product for the forgery-proof document. In order to enable the use of simple flatbed scanners in the verification, a special calibration element is introduced according to DE 10 2005 013 962 A1.

The above-mentioned prior art has in common that for the generation of the security code, the data memory of each individual data carrier must be read out. In the case of printed optically readable data storage, each data storage must be recorded with a scanner or a camera. Despite the production of semi-finished products proposed in DE 10 2005 013 962 A1, the production remains relatively complicated.

Furthermore, the codes must be printed with high spatial resolution in order to have sufficient memory capacity for applications. A high spatial resolution is also necessary for a secure counterfeiting contactor, because only then is the printed image individual. This is especially true in the production in offset or flexographic printing. Printed raster print data memories of high spatial resolution unfortunately require relatively expensive optoelectronic readers with high spatial resolution.

The invention is therefore based on the object of the known methods, techniques and markers to expand to the effect that for a mass-produced raster print data storage a cost-effective security code is provided, which makes it possible to detect illegal copies with simple means. The method should be particularly suitable for labeling of products or packaging with the aim of combating piracy and it should be easy integration in printing or packaging machines to be possible. The detection of counterfeit packaging should also be possible without individual scanning of each printed product or package.

Furthermore, the detection of counterfeit products using the camera of a mobile terminal, such. with a mobile phone, simple and inexpensive.

To solve the problem, the following terms are used in the following remarks:

a) grid point: smallest area in a digital raster image that can be filled with color or embossed or engraved b) grid cell: a coherent area made up of at least one grid point c) pressure symbol or symbol:

Grid cell with defined occupied grid points for information coding d) S2i symbol: Symbol according to DE10 2004 036 809 A1 e) Raster print data store: a printed, embossed, engraved or otherwise produced data store constructed from print symbols f) S2i raster print data store:

G) color screen cell: grid cell composed of halftone dots of different or the same color, which produces a visual color impression when viewed with the human eye h) Colored print symbol or color symbol: color grid cells with defined screen halftone dots for information coding i) color screen print data memory: a raster print data memory constructed from colored print symbols j) Fractal raster print data memory: a raster print data memory which is decodable with different triggering of the readers; a special case is a color raster print data memory constructed of print symbols. k) epicode: a random code created during the production of a raster print data memory

To solve the problem as stated above, the procedure is as follows: The individual data memories are produced in a multi-stage production process. Multi-stage manufacturing processes are e.g. Printing methods in which the printing ink or the printed image is brought onto a printing material by means of a printing form, such as, for example, in the case of the high-pressure method (letterpress printing, flexographic printing or embossing in which a printed image without color is formed, etc.), in the planographic printing process (offset printing, lithography, etc.), gravure printing (doctor blade gravure, steel engraving, etc.) or in the screen printing process.

Multi-stage manufacturing processes are also found in color printing machines (e.g., color laser printers or color ink jet printers) in which the color image is composed of multiple color components.

In the production of a tamper-proof raster print data storage according to DE 103 45 669 A1 in offset printing, a completely unexpected observation resulted in a mass production: A first security code is created by the individuality in the production of the printing form for offset printing. The cause of the individuality may e.g. through the individuality of the material, through

Wear of a tool or by inaccuracies of manufacturing machines arise and is immaterial in the context of the invention. The security code may be obtained by a survey (e.g., image capture, 3D survey, etc.) of the printing form. In complete analogy to DE 103 45 669, the target-actual deviation between the actual printing form and the desired

Printing form determined and evaluated. Particularly advantageous for this purpose are the decoding of the measurement signal and the evaluation of the resulting Error signal. This can be done, for example, by quantizing the difference between the so-called soft decision values and the decision values after the usual error correction. In this step, 3-D measurement signals can also be reduced to 2-D data fields, in complete analogy to the reduction of two-dimensional pixel fields to information bits in the decoding of matrix codes (see DE 10 2004 036 809 A1).

The individuality of the printing form can also be determined by means of (trial) printing. In this case, the individuality of the printing form is superimposed by the local individuality of the (possibly flowing) printing ink and the printing substrate. By averaging the target-actual-calibrations at the different pressures, the individuality of the printing form is determined. The individuality of the printing form according to the invention is the basis for a security code that hovers over the actual data with the production of the printing form, previously unused. Quantization of the target-actual deviation results in a security code, which will henceforth be called the epicode of the printing form.

The epicode can now (possibly with PKI, public key infrastructure, encrypted /

Encryption) are stored in a database or it is encrypted (for example with PKI) stored on the disk and uniquely identifies all

Datastores that were made with a particular printing form. Preliminary experiments show that an offset-printed raster print data store with a surface area of only 1 cm2 has a detection confidence better than one in a million.

The use of a printing plate in print production is already a two-stage production process in itself. In certain printing processes, the printing form itself is created again in a multi-stage process. For example, in offset printing, a film may first be exposed, after which a printing plate is produced using the film. In this case, each manufacturing step generates its own epicode, which can also be determined separately. Specifically, first the epicode of the film is measured and then the epicode of the printing form, which contains the epicode of the film. In general, the individual epicodes of each stage for many manufacturing processes, at least in (local) spectral bands, are, to a good approximation, independent, additive, mean-free quantities, which can therefore be separated by averaging. This makes it possible to determine, for example, whether several printing plates were created with the same film original, as will be explained in more detail later. In multilevel printing processes, however, statistical relationships between the individual levels can also arise, which can be characterized by statistical methods, such as Hidden Markov models. The characteristic model parameters can also be used to detect forgeries.

With the production of data storage, the printing form is exposed to natural wear. This slowly changes the epicode of the printing form. This change is recorded during production (possibly also in the form of an estimated model) and stored in the database. As a result of this procedure, a so-called overproduction can in principle also be recognized despite the use of the same printing form. If a manufacturer produces more data stores than the owner of the data allows, the overproduced data stores will have an increasingly different epicode and illicit production may be detected. Also, the removal of data storage during production will be detectable by jumps in the epicode.

However, low overproductions, which could possibly be considered as counterfeits or identified, are not recognizable due to the epicode of the printing form.

A second security code solves the resulting additional task. For this purpose, the epicode of each individual pressure is determined, as already described in DE 103 45 669 A1. The epicode of the printing plate can then, at least in certain (local) frequency bands, by averaging the

Epicodes of individual prints are determined. The method described in DE 103 45 669 A1 can thereby, as first experiments show, unexpectedly strong can be improved by the epicode of the printing form is deducted from the epicode of the individual printing.

Regarding the procedure for detecting illegal copies, the readers use the following procedure:

The reader determines the epicode of the data store and correlates it with the target epicode of the particular stage of the manufacturing process. The SoII epicodes can be loaded from a database or read from the data store and decrypted. Only the target epicode of the last stage of the manufacturing process is an individual code that has to be stored per single print. The target epicodes of all other stages are not variable or can be modeled by constants and thus can be stored as constant data in a memory area of the data carrier (for example with PKI) in encrypted form (for example, machine-readable). This saves the database. Preferably, the data memory described in DE 10 2004 036 809 A1 is used for this purpose.

Since the individual Epicodes describe the natural individuality of the stages of the manufacturing process, the Epicodes can not be falsified systematically in principle. A counterfeit attack can only start with the used cryptography.

The epicode principle can be transferred to other storage technologies and in particular to 3-dimensional storage structures.

In special applications, it may be useful to provide the printing form itself or any other dimensionally stable object with a copy detection. For this purpose, the printing form or the article, which were possibly produced for a completely different (printing) application, receive a raster print data memory, which is measured and evaluated as described above. The (possibly encrypted) data in the memory can then be stored e.g. describe the owner, the manufacturing process, the date of manufacture, etc. For example, laser-engraved printing plates for flexographic printing,

Stamp, rubber parts or glass parts are marked in such a way. A possible application of the above-described copy protection method is possible in particular in indirect printing methods, which was also described above under the name of multi-stage printing method, as can apply to the offset or gravure printing method.

The printing form (e.g., printing plate, gravure roll / gravure printing cylinder in gravure printing, etc.) serves as a transfer member for the ink, on which a targeted distribution of color through previously generated surface properties (surface tension, cell distribution) is made possible. Each printing plate has specific properties due to its production, which enables unambiguous recognition by the method described above.

This specific for a specific print job or edition edition fingerprint is sufficiently different from a print with another printing plate. In the method, however, it should be noted that process-related changes may occur that may limit the visibility of said fingerprint.

For this reason, it is useful to print multiple copies of the printed code in order to document these process-related changes and to enable unambiguous assignment with sufficient selectivity.

In practice, the handling may be such that during a run periodically data codes and the associated epicodes are captured and stored by the printed surface. Possible variants of the method are then designed as follows:

A. Combination of the recorded data code in the database with individual process information (serial number, process parameters such as speed, setting, materials used ....) B. Detection with a handheld device (video magnifier, scanner) outside the production machine

C. Automatic detection with a suitable camera in the production machine D. Detection by reading using a two-dimensional reading table outside the machine.

In this case, the acquisition of one or more datagrids can take place in different ways: a. fully automatic by an independent recognition of the position of the markings. The recognition software is able to recognize the typical Datagrid features in the printed areas of the sheet and to read them in here. Depending on the distribution of the benefits, scanning should be one-dimensional or two-dimensional. b. fully automatic and self-learning (storing the position to scan faster in further measurements). c. supported by data from the precursor / printing form creation to control the reading position.

The frequency of data collection can be triggered by various events:

I. Specification of a sheet number to be printed

II. Procedure according to the processes involved in the printing process (interruption of production, washing, color control, etc.) III. Exceeding previously defined technical printing limit or

Characteristic values (dot gain, density, color locus or the like) which may have been recorded with measuring devices that are available on the press and used inline or manually.

The sheets to be measured can be manually removed on request by a signal (acoustically or visually) or automatically discharged (eg, sheet diverter), if necessary also fed to the detection device. Another embodiment is that the data codes recorded during the manufacturing process are compared and evaluated. If the number of copies is high, it is to be expected that typical changes will occur as a result of

- contamination and wear of the components involved in the ink flow (rollers, cylinder surfaces),

- Process fluctuations (color and dampening solution guidance, temperature conditions, roller contact zones, deposit formation, machine operation and adjustment u.v.m.) and

- Environmental influences (climate, materials)

As evaluation criteria, algorithms of image processing can be applied to the datagrids, which are also set in correlation with quality criteria typical of print quality (dot gain, density, color location, minimized dampening solution guide).

This evaluation provides information that can be provided to the printer for operation to take action, if necessary, to achieve a stable print quality. Also possible is an automatic tracking of the corresponding manipulated variables (for example, colorant and fountain solution guidance, temperature ....).

A particular application of the invention is seen in the manufacture of so-called blister packages in which a tool is used to bond a cover sheet to a backing material, usually with the aid of pressure and temperature. The tool usually consists of a dot matrix. This dot matrix is replaced by a raster code data memory and thus allows a forgery-proof identification of the blister.

The task of decoding the raster code data memory using the camera of a mobile telephone or another mobile terminal has not yet been solved and to recognize counterfeits with the help of the Epicodes. A problem is the low spatial resolution of the cameras, which is not sufficient to resolve the individuality of the print.

The object is achieved by a colored raster print data memory according to main claim 6. By designing the raster print data memory as a color code and producing it in a multi-step printing process, a relatively easy-to-measure epicode is created as it were. Each color component of the memory is generated by its own printing stage, whereby the color components always have a random offset. In printing processes using printing plates, there is a separate printing plate for each color component. Each printing plate produces an epicode. But also the always occurring offset of the printing plates in the production machine as well as the additional offset of the color components by positioning inaccuracies of the paper guide during printing produce an epicode that can be used for the protection against counterfeiting. Colored digital printing techniques, such as Color laser printing or color inkjet printing, are also seen as a multi-stage printing process in the context of the invention. It is particularly advantageous that the information is stored in the color screen data memory with which multi-stage manufacturing process of data storage was produced. Of course, the information can also be stored indirectly via a stored database or Internet address.

In principle, all known color 2D matrix codes can be used as the color screen data storage if the print resolution is chosen to be high enough.

Particularly advantageous is the use of a color screen print data storage according to claim 8. The mathematical meaning of the orthogonality of the symbols is now extended to the colors. This means that unprinted areas are printed with complementary colors for coding.

Claim 9 describes the overlaying of the color raster print data memory with an additional micro-grid, which again as a raster print data memory is designed. Such a fractal raster print data memory places particularly low demands on the printing technology and can also be decoded with readers of different spatial resolution. With locally high-resolution (possibly monochrome) readers, more information than with a low-resolution color sensor can then be extracted. In addition, an additional epicode of higher security is created. This is particularly interesting when used for counterfeit protection, in which readers are offered for different security levels.

Fractal raster print data memories are an easy way to provide any monochrome barcodes or 2-D barcodes with a security code (Epicode) according to the invention, according to claim 10. Rasterized the printed and unprinted areas of the monochrome barcode and in different, preferably complementary colors Thus, from such printing by color image processing, a monochrome image of the original bar code and a monochrome raster image can be produced. From the monochrome raster image, the EpiCode can then be extracted. Of course, the grid can preferably be designed as a raster print data store.

1 shows the prior art disclosed in DE 10 2004 036 809 A1 for a so-called S2i raster print data memory which is constructed from raster cells which are composed of 6 × 6 raster dots. The symbols 5, 6, 7, 8 used for data storage of 2 bits are constructed from the mathematically orthogonal patterns 1, 2, 3, 4. The pattern pairs 1 and 2 each have the diagonal corners and the pattern pairs 3 and 4 the adjacent middle fields. In each case one of the pattern pairs is selected to obtain the symbols 5, 6, 7, 8.

Fig. 2 illustrates the transition to the color raster print data memory. Different colors are represented by different textures. The new pattern 9 is created by combining the pattern 1 with the pattern 2. Pattern 1 and pattern 2 are preferably in complementary colors executed, eg in the combinations red cyan, green - magenta, blue - yellow or as a special case white - black. In the pattern 9, the diagonal corners of a rectangular field are respectively occupied by pairwise complementary colors, eg red cyan. Pattern 10 is complementary to pattern 9. When using the four colors red, green, blue and black as well as the corresponding complementary colors cyan, magenta, yellow and white, patterns 9 and 10 can be used to encode eight different states and thus three bits , Pattern 11 is formed by performing and combining patterns 3 and 4 preferably in complementary colors, ie, the unoccupied fields of patterns 9 and 10, respectively, are occupied on the respective opposite sides by pairwise complementary patterns. This allows further 3 bits to be coded. 13, 14, 15, 16 show by way of example how the patterns 9, 10, 11, 12 are combined to form color symbols. There are a total of 64 different combination options, which corresponds to a coding of 6 bits. Additional storage of 3 bits can be achieved by occupying the central panel with one of the 8 colors. In a color symbol, a total of 9 bits are encoded. Individual halftone dots or even groups of halftone dots may shift slightly during printing with respect to the nominal grid, which is indicated in the figure. A further increase in information density results from the use of additional colors and their complementary colors.

FIG. 3 shows the prior art disclosed in DE 10 2004 036 809 A1 for a special S2i raster print data memory, as it is used in particular at high print resolutions. The symbols 17, 18, 19, 20 are formed from the symbols 5, 6, 7, 8 by omitting individual grid points on the edge, taking care that the patterns selected from the pattern pairs adjoin in as many grid points as possible. The omission of the halftone dots allows a targeted color bleeding and promotes a clear expression of the epicodes. In the symbols 21 to 28, the grid points in the middle of the grid cell are occupied to different degrees. FIG. 4 illustrates how the color symbol 9 in FIG. 2 forms a fractal color blank data memory. Different colors are represented by different hatching. The color print symbol 9 initially has 6x6 color grid points. Each 2x2 color grid points have the same color. These 2x2 color raster points are now replaced by 2x2 symbols 17 to 28 of FIG. The symbols of this fractal color raster print data memory consist of (6x6) x (6x6) halftone dots. At 70 dpi color grid cells, the microscopic dot resolution corresponds to 70x6x6 = 2520dpi. In a four-color print with the basic colors cyan, magenta, yellow and black, the patterns in the colors cyan, magenta, yellow and black are rasterized by 6x6 monochrome symbols. Patterns in the colors red, green and blue are achieved by additive color mixing.

Using the inks cyan, magenta, yellow and black, e.g. the color blue due to the mixture of magenta and cyan. In the case of symbols 21 to 28, black is added in the middle. Correspondingly, green and red are formed by mixing cyan with yellow and yellow with magenta. The color white can be achieved by combining blue, green and red symbols. The color screen data memory according to FIG. 4 can be recorded with the camera of a mobile phone without special intent optics and decoded by the computer of the mobile phone. The relatively high demands on the color print cause a (color) epicode, which is surprisingly usable for the recognition of a copy. The fine grid underlying the color symbols can additionally be recorded and decoded using high-resolution monochrome or color cameras.

This results in an additional data storage and an additional, local high-frequency epicode, which is suitable for forgery protection with high security requirements.

By omitting and supplementing grid points on the edge of the symbols, the brightness, or more precisely the brightness impression of the color symbols, can be changed and additional information can be stored. In summary, the color raster print data memory described in FIGS. 1 to 4 enables simple production in the mass printing method and at the same time testing and decoding with the aid of digital color cameras, as are installed in many mobile telephones.

Of course, the color screen accumulator can also be designed differently. For the purposes of the invention, any color image produced in raster print can be used as raster image with superimposed epicode used according to the invention. The raster image encodes image information which - due to the redundancy in real images - can be decoded without errors after production despite errors. The epicode arises almost incidentally through the manufacturing process and is u. a. by the individuality, the pressure levels or printing plates responsible for the individual color components and their interactions. Due to the error-free decoding of the image information, a detection of the epicode is possible after production.

Claims

claims

1. A method for generating a security code for a, applied by means of a multi-step printing process on an object, optically readable raster print data memory high density, characterized in that at least a part of the security code by the random deviation of at least one stage of the manufacturing process of an average or a desired value arises and this deviation causes a measurable modulation deviation in the raster print data memory and from this the security code is calculated.

2. A method for generating a security code according to claim 1, characterized in that the manufacturing process uses a printing form, measure the individual printing form, compared with the desired printing form and from this a security code is calculated and stored.

3. The method according to claim 2, characterized in that the security code is obtained by decoding the measurement signal and a comparison of the soft decision values with the code bits after an error correction.

4. The method according to claim 3, characterized in that the soft decision values are determined by the evaluation of at least two proofs.

5. The method according to claim 4, characterized in that the temporal change of the soft decision values in the production of raster print data storage is detected.

6. object with applied raster print data storage, which from

Grid cells with predefined shape and relative position, which in turn Raster points of predefined form and relative position consist, is constructed, characterized in that in at least one of the grid cells i) for optional coding of at least two information bits halftone dots of the diagonal edge areas top left and bottom right or this non-overlapping edge areas right above and bottom left with one of at least two selectable colors are printed, ii) for the optional coding of at least two information bits halftone dots of the vertical edge areas above and below or for this non-overlapping horizontal edge areas are printed right and left with a minimum of two selectable colors, iii) all selectable colors in the raster print data memory, and iv) a security code consists at least in part of a deviation of the relative position of the raster cells or raster points from the defined position.

7. An article according to claim 6, characterized in that one of the selected colors is black.

8. An article according to claim 6, characterized in that the corresponding i) and / or ii) each unprinted areas are printed with complementary colors to the printed areas.

9. An article according to claim 7, characterized in that the halftone dots have a micro-screening in the form of a raster print data memory.

10. An article according to claim 6, characterized in that the screening is superimposed by a monochrome barcode or a matrix code.

11. Printing machine for carrying out a method according to claim 1 for producing an article according to claim 6 with one or more printing units having a sheet leading impression cylinder and at least one printing forme cylinder, wherein on the printing form cylinder, a printing form is clamped, which serves as a transfer element for printing ink in a targeted distribution of the ink by previously generated surface properties on the object is used, wherein in or in connection with the printing machine, a measuring or recording device for detecting a raster printed data storage device applied to the article by means of the printing plate is provided.

12. Printing machine according to claim 11, characterized in that the measuring or recording device is arranged as a handheld device such as a (video magnifier or a scanner outside the printing press.

13. Printing machine according to claim 11, characterized in that the measuring or recording device is arranged as an automatic detection device with a suitable camera within the printing press.

14. Printing machine according to claim 11, characterized in that the measuring or recording device is arranged as a two-dimensional reading table with a device for imagewise recording of raster images outside the printing press.

15. Printing machine according to claim 1 1 to 14, characterized in that a control is provided, by means of which the data areas of the raster print data storage are fully automatically selected by autonomous recognition of the position of the raster data storage memory Markings gene, with benefit areas are considered on the object and one scan is done once or twice.

16. Printing machine according to claim 11 to 14, characterized in that a controller is provided, by means of which the data areas of the raster print data memory selected by a controlled detection of the position of the raster data memory on the basis of data from the prepress and / or the printing form to control the reading position become.

17. Printing machine according to claim 11 to 16, characterized in that the determination of the frequency of data acquisition is triggered by - specification of a sheet number to be printed and / or

- Processes caused by the printing process, such as production interruptions, washing or color control and / or

- By exceeding of defined printing technical limit or characteristics such as dot gain, density or color location o. Ä ..

18. Printing machine according to claim 11 to 17, characterized in that recorded during the manufacturing process in or in conjunction with the printing machine DataCodes are compared and evaluated, with typical changes are determined and stored in the printing units of the printing machine by

Contamination and / or wear of the components involved in the color flow, such as rollers or cylinder surfaces, and / or

- Process fluctuations such as in the inking and dampening solution guide of the printing press, temperature conditions, roller contact zones, coating formation, machine operation and / or adjustment and / or

- Environmental influences such as climate and / or materials arise.