WO2016128327A1 - Identification document comprising a personal image - Google Patents

Abstract

The invention relates to an identification document (100) comprising a personal image (101), a testing matrix (103, 803, 901) being superimposed on said personal image (101) and said testing matrix (103) comprising a first testing matrix field (105) and a second testing matrix field (107), said first testing matrix field (105) having a first printing ink (106) designed to reflect light in a predetermined wavelength range, and the second testing matrix field (107) being devoid of this first printing ink.

Description

 Identification document with a person picture

The present invention relates to an identification document.

A modern identification document such as identity card or passport includes not only security features which serve to verify authenticity of the identification document, but also a person image of a person to be identified.

In an attempt to forge an identification document, however, not only the security features but also the person image are usually manipulated. While verification of the authenticity of some security features can be performed automatically, automatic verification of the authenticity of personal images is difficult. One reason for this are the different qualities of images of persons and, not least, the different characteristics of persons' faces.

It is therefore the object of the present invention to provide an identification document in which an automated verification of the authenticity of a person image can be performed.

This object is solved by the features of the independent claims. Advantageous forms of further development are the subject of the dependent claims, the description and the attached figures. The present invention is based on the finding that the above object can be achieved by a test matrix superimposed on the person image with at least one printing ink which is reflective in a non-visible light wavelength range, for example in the infrared wavelength range or in the ultraviolet wavelength range.

According to a first aspect, the invention relates to an identification document with a person image, wherein a test matrix is superimposed on the person image, wherein the test matrix has a first test matrix field and a second test matrix field, wherein first test matrix field comprises a first ink formed to reflect light in a predetermined wavelength range, and wherein the second test matrix field is free of the first ink. The test matrix is preferably formed by the test matrix fields and superimposed on the person image. For example, the second test matrix field can not have any ink at all.

Thus, the test matrix may be populated by the first test matrix field or by a plurality of first test matrix arrays to provide a test pattern for examining the authenticity of the person image that is light reflective in the predetermined wavelength range. However, the second test matrix field may also have an ink which differs in optical properties in the predetermined wavelength range from the first ink. Thus, the first test matrix field or the first test matrix fields and the second test matrix field or the second test matrix fields have different optical properties in the predetermined wavelength range, whereby an automated verification of the authenticity of the person image can be realized.

According to one embodiment, the second test matrix field comprises a second printing ink, wherein the first printing ink and the second printing ink are configured to reflect different spectra of the predetermined wavelength range, or wherein the second printing ink is transparent in the predetermined wavelength range.

The predetermined wavelength range may be, for example, the ultraviolet wavelength range having an ultraviolet A spectrum or an ultraviolet B spectrum or an ultraviolet C spectrum. For example, the first ink may be reflective in the ultraviolet A spectrum while the second ink is reflective in the ultraviolet B or ultraviolet C spectrum. However, the first ink may also be reflective in the ultraviolet B spectrum or in the ultraviolet C spectrum, while the second ink is reflective in one of the other ultraviolet spectra. This ensures that the first printing ink and the second printing ink have different reflection properties. According to one embodiment, the test matrix comprises a third test matrix field with a third printing ink, wherein the third printing ink is designed to reflect light in the predetermined wavelength range. In this case, the first printing ink, the second printing ink and the third printing ink reflect light in different spectra of the predetermined wavelength range, for example in different ultraviolet spectra of the ultraviolet light, whereby different reflection properties of the test fields in the specific wavelength range can be realized. As a result, a color coding of information, for example a person's date or a document date, can be realized. In one embodiment, the first ink is configured to reflect light in the ultraviolet A wavelength range, the second ink being configured to reflect light, particularly in the ultraviolet B wavelength range. The different printing inks may, for example, reflect different printing inks or different spectra of the same wavelength range, as a result of which color coding of information, for example a person's date or a document's date, can likewise be realized.

According to one embodiment, the predetermined wavelength range is an ultraviolet wavelength range. By means of the majority of the test matrix fields, different assignments of the test matrix with the first, optionally the second, and optionally the third, printing ink can be achieved, whereby, for example, personalized coding of the test matrix or color coding can be realized.

According to one embodiment, one or more test matrix arrays may be unoccupied and free of ink that is reflective or absorbing in the first wavelength range.

According to one embodiment, the arrangement of the respective check matrix field in the check matrix depends on a person's date or on a document date or is determined by an encoding of a person's date or a document's date. The arrangement of the first test matrix field or of a plurality of first test matrix fields in the test matrix and the arrangement of the second test matrix field or a plurality of second test matrix fields in the test matrix can be used, for example Person data or be predefined for a document date or derivable from a person's date or from a document date. However, the arrangements of the test matrix fields in the test matrix can be fixed and be fixed and predetermined, for example, for a specific group of persons or for a specific type of identification document, for example an identity card or a passport.

According to one embodiment, the arrangement of the respective check matrix field is determined by a binary or binanned person data or by a binary or binarized document date or is determined by an encoding of a person date or a document date or by an asymmetric or symmetric encryption or by a digital signature of a person's date or of a document date or is determined by a hash value of a personal date or a document date. When using a digital signature, a signature can be formed in the document production with the private key from real data (share)

Coding of the test matrix is used or where certain values or parts of the signature or a mapping table are used. During the check, the matrix code can then be read, possibly supplemented with other data of the identification document, if, for example, the storage capacity of the matrix code for a secure signature is possibly too limited, and the authenticity of the real data (parts) is determined with the public key.

According to one embodiment, the real data can be read in, for example by means of software, and form the code according to a corresponding algorithm. The code calculated from the read person or document data (or parts thereof) can then be compared with the read code for correspondence. If the person's date or the document date already exists in binary form, then, for example, the respective binary position can code a position of the respective test matrix field in the test matrix. For example, if the matrix fields are numbered consecutively, then the fifth binary location may indicate that it is a fifth matrix field in the test matrix. By grouping the binary digits, however, any arbitrary addressing of the test matrix fields can be achieved. On the other hand, the significance of the respective binary number can indicate whether a first printing area with the first printing ink or a second printing area with the second printing ink should be arranged in the respective test matrix field. For example, the binary number 1 may indicate the first ink and the binary number 0 the second ink, or vice versa.

If, on the other hand, the personal date or the document date are not in a binary form, they can be converted into a binary form by binarization. In this case, for example, each letter can be assigned a binary number. Similarly, Arabic numerals can be represented directly in binary. With the binarization achieved in this way, the assignment of the matrix in the first and second test matrix field can be carried out as explained above. However, the arrangements of the first and the second test matrix fields, that is to say the assignment of the matrix fields of the test matrix, can also be achieved by an encryption of a person's date and / or a document date. This encryption can be symmetric encryption or asymmetric encryption using cryptographic keys. In addition, one or more hash values can be generated from the person date and / or from the document date using a predetermined hash value map. By the encryption or by the hash value formation again arise binary representations, which as stated above indicate the arrangements of the first and second pressure ranges and thus the matrix assignment.

According to one embodiment, it is also possible to provide tertiary or even higher-value codings or representations. This can be based on, for example

different values and colors can be realized. Thereby, more than two binary coding or display possibilities can be provided, for example when using three colors or three colors plus one value (lack of printing ink), so that also tertiary or further coding, also on others Number systems with different base numbers, such as 4, 5 or 10, based give. A matrix field can thus represent two or more than two values.

If the test matrix has, for example, two columns and three rows, the result is a total of six matrix fields, which can be assigned either to the first printing area or to the second printing area. This results in an arrangement pattern of the first test matrix fields and / or the second test matrix fields and optionally of third test matrix fields, which can be checked using a reference arrangement pattern or, in the case of an arrangement pattern layout, by a binary reference number.

According to one embodiment, the check matrix forms a bar code or a multidimensional and optically detectable code, the code providing coded data, in particular a person data or a document data or derivatives thereof.

Due to the geometric arrangement of the test matrix fields, it is possible to generate graphic patterns which, for example, form a two-dimensional QR code. The optically detectable code may provide encoded data, such as an encoded person's date or a coded document date. By the optical detection of the code as well as by the decoding the data can be recovered and compared for example with reference data.

According to one embodiment, a checksum may be a number, in the visible

Wavelengths are not visible, for example, in the ultraviolet range printed on the person image. The checksum can be 1 or more digits and can be calculated, for example, based on a document date, person data or derivations thereof.

According to one embodiment, the test matrix is printed on a document body above the person image or the test matrix is printed on a film which is arranged above the person image, in particular glued or laminated. The document body may comprise, for example, laminated plastic layers, so that the person image is printed in a first plastic layer, while the test matrix is formed in an overlying plastic layer which overlays the first plastic layer becomes. However, the test matrix can also be printed directly on the person image or mounted on a film which is adhered to a surface of the document body.

According to one embodiment, the respective printing ink is transparent in the visible white light wavelength range. Thus, the printing inks cover the

Person picture in the visible light spectrum not.

According to one embodiment, a test matrix having a first test matrix field and a second test matrix field is superimposed on a person image, in particular superimposed by printing or gluing, wherein the first test matrix field has a first printing ink which is designed to reflect light in a predetermined wavelength range, and wherein the second Test matrix field is free from the first ink.

According to one embodiment, the method comprises determining the occupancy of the test matrix with the first test matrix field or with a plurality of first test matrix fields and with the second test matrix field or with a plurality of second test matrix fields. This determination can be made, for example, by encoding a person's date or a document date, or by encrypting a person's date or document date, or by hash value generation from a person's date or from a document date.

According to one embodiment, the check matrix fields are arranged in the form of an optically detectable code, for example a bar code or a multi-dimensional code, such as a QR code.

In one embodiment, the method comprises laminating a first plastic layer comprising the person image and a second plastic layer having the test matrix to overlay the test matrix with the document image.

According to a third aspect, the invention relates to a document reader for detecting the authenticity of an identification document which has a person image and a test matrix superimposed on the person image, the test matrix being a first Test matrix field and a second test matrix field, the first test matrix field having a first ink which is adapted to reflect light in a predetermined wavelength range, and wherein the second test matrix field is free of the first ink, with an image pickup device for detecting a recording of the example printed Person image in the predetermined light wavelength range and a processor which is adapted to detect in the recording, the test matrix with the first test matrix field, which is light-reflecting in the predetermined wavelength range.

The predetermined wavelength range may be, for example, the ultraviolet wavelength range. The document reader can preferably be used to verify the authenticity of the identification document according to the invention, in particular the authenticity of the person image of the identification document according to the invention. The image recording device is preferably designed to detect the recording in the predetermined wavelength range, for example in the ultraviolet wavelength range. The image recording device is preferably a digital image recording device, so that the image is available digitally and can be supplied to the processor in the form of image data. The processor captures in the image those fields which have a reflection in order to detect the first test matrix field or an array of first test matrix fields and of second test matrix fields. For example, the processor may exploit information about the size of the test matrix, which may be a 2x2 or a 2x3 test matrix or other test matrix, to selectively search for test matrix fields which are reflective. In this case, the processor can be configured to compare the acquired image information with a threshold value, for example with a brightness threshold, in order to detect the reflective, brighter test matrix fields. If the test matrix fields of the test matrix are covered with different printing inks, which are reflective at different spectrums of the predetermined wavelength range, for example at different ultraviolet spectra, then the test matrix can also provide color coding, which the processor can decode. Here is the Processor adapted to search in the aforementioned different spectra of the predetermined wavelength range for Prüfmatrixfeldern to detect a colored array of Prüfmatrixfeldern, which may also encode information. This color information can be decoded in a manner known per se, and the decoded information can be compared with a reference information in order to check the authenticity of the identification document or the person image.

In one embodiment, the processor is configured to detect an arrangement of the first test matrix field and an arrangement of a second test matrix field or a third test matrix field in the recording of the person image and to decode the decoded arrangement as a barcode or multidimensional code, to decrypt or to a reference arrangement or to detect a color coding of the test matrix with test matrix fields reflecting different spectrums of the predetermined wavelength range, and to decode the detected color code to detect the authenticity of the identification document.

According to one embodiment, the document reading device comprises a light source, which is designed to illuminate the identification document with light in the predetermined wavelength range, in particular in the infrared wavelength range or in the ultraviolet wavelength range, for recording the person image. The light source may be, for example, an infrared light source or an ultraviolet light source. The lighting may include, for example, a top lighting or a backlight.

According to one embodiment, the document reader comprises a document support, which is transparent in the predetermined wavelength range. In this case, the light source can be arranged below the document support and illuminate the applied identification document through the document support in order to obtain the image of the person image.

According to one embodiment, the document reader is a mobile document reader, for example in the form of a smartphone. The light source can be realized in this case by the integrated image illumination of the smartphone, which is designed or driven to emit light in the predetermined wavelength range.

According to one embodiment, the processor is designed to detect an arrangement of the respective reflective test matrix field (s) in the recording of the person image and to decode, decrypt or compare the detected arrangement as multidimensional code with the reference arrangement in order to verify the authenticity of the identification document capture.

By way of example, as stated above, the arrangements of the reflective test matrix fields encode a binary or a higher-order, for example ternary, number which, for example, can be compared with a reference binary number to detect the authenticity of the printed person image.

According to one embodiment, higher-order number systems, for example the base number 8 octal system or the base number 10 decimal system, can also be used. According to one embodiment, other bases may also be used. For example, the number system with the base number 4 with 3 UV colors allows 4 possible values per matrix field.

According to one embodiment, the arrangements of the first to second printing area form a bar code or a multi-dimensional code, in particular an optically detectable code, such as a QR code, which can be decoded in a manner known per se in order to obtain coded information or coded data and to use these to verify the authenticity of the identification document. In one embodiment, the arrays of the reflective test matrix arrays form a graphical pattern that can be compared to a reference graphic pattern to capture the authenticity of the identification document. In all aspects and embodiments of the invention, the person's date may include a name, birthday, address, or other indication regarding the person depicted on the person's image. The document date may have a document number, a date of issue, or an expiration date, with or without a check digit. The document data may further include at least a date of a machine-readable zone or parts thereof of the identification document. Thus, the arrangements of the test matrix fields can be assigned to specific personal data and / or document data. This assignment can be fixed or determined by an encoding. Further embodiments of the invention will be explained with reference to the accompanying figures. Show it:

1 shows an identification document; FIGS. 2a to 2c show representations of a test matrix;

FIGS. 3a to 3c representations of a test matrix;

FIGS. 4a to 4e representations of a test matrix;

FIGS. 5a to 5e representations of a test matrix;

FIGS. 6a to 61 show representations of a test matrix; FIGS. 7a to 71 show representations of a test matrix;

8a to 8g representations of test matrices;

9q to 9f representations of test matrices; and Fig. 10 is a schematic diagram of a document reader. 1 shows a schematic representation of an identification document 100 which has a person image 101 to which a test matrix 103 is superimposed. The test matrix 103 comprises rows and columns which define test matrix fields with a first test matrix field 105 and a second test matrix field 107. The test matrix 103 may comprise a plurality of first test matrix fields 105 and a plurality of second test matrix fields 107.

The first test matrix fields 105 are printed with a first ink 107, which is light-reflecting in a predetermined wavelength range. The predetermined wavelength range may be, for example, the ultraviolet wavelength range. By contrast, the second test matrix fields 107 are free of the first printing ink 105 or transparent. According to one embodiment, the test matrix fields 107 are free of any printing ink. According to a further embodiment, the second test fields 107 may comprise a second printing ink, which is also reflective in the predetermined wavelength range, but in a different spectrum than the first printing ink 105. As a result, a color coding is achieved.

For example, the first ink 105 may be reflective in the ultraviolet A wavelength range, while the second ink not shown in FIG. 1 may be reflective in the ultraviolet B or ultraviolet C spectrum, or vice versa.

The identification document may further comprise, for example, a document date, for example a document number, which is arranged in a machine-readable zone 109 of the identification document 100. The assignment of the fields of the test matrix 103, that is to say the arrangements of the respective test matrix field 105, 107, can, for example, be used to binarize the document data 109, ie to convert it into a binary representation. In an analogous manner, for example, a person's date, for example a person's name or an image information, can be binarized, ie converted into a binary representation. Fields of the test matrix 103 can be addressed simultaneously with the binary representation, and it can simultaneously be indicated where the first test matrix regions 105 and / or where the second test matrix regions 107 should be located. The second test matrix field 107 may be free of the first ink 106. However, according to one embodiment, the second test matrix array 107 may comprise a second ink which also reflects light in the predetermined wavelength range, but in a different non-visible light spectrum than the first ink 106. If the predetermined wavelength range is the ultraviolet wavelength range , this can be realized by a color coding, wherein a color choice, for example, can change a matrix and can correspond to a coding. In this case, the color pattern can be permanently or dynamically coded, for example as a function of a person's date or of a document date. In this way it is also possible to use a plurality of distinguishable ultraviolet colors, for example red, green or blue, or else a combination of a color coding and a matrix coding. In addition, the different reflectable spectra may be ultraviolet spectrums of type A, B or C.

In the exemplary embodiment illustrated in FIG. 1, the test matrix 103 comprises two rows and two columns. However, the number of rows and / or columns may also be dynamically coded, for example, depending on a person's date or a document date, such as a document number, a date of a document issue, or an expiration date. In this way, the size of the test matrix 103 can be variable.

FIG. 2 shows exemplary embodiments of a coverage of the test matrix 103, for example 2 × 2, with a light-reflecting printing ink, for example with the first printing ink 106. As shown in FIG. 2 a, the test matrix fields which are to have a light-reflecting printing ink can be provided with the plus sign be, while Prüfmatrixfelder, which should have no light-reflecting ink, may be provided with the minus sign. The arrangement of the plus and minus signs can be fixed for a group of people, for a kind of identification document or for certain countries. However, the arrangements of the plus or minus signs may be personalized and depend on a person's date, document date or a coding of this data or an encryption of this data. As shown in FIG. 2 b, this results, for example, in the first test matrix fields 105 in the arrangement shown by way of example in FIG. 2. The second test matrix fields 107 are, for example, free of the first printing ink 106 in the exemplary embodiment shown in FIG. 2, so that the pattern shown in FIG. 2c results in the case of illumination in the predetermined wavelength range, for example in the case of UV illumination. The second test matrix areas 107, which are free of ink, appear dark, while the first test matrix areas 105 are reflective. The reflection pattern can be detected and used to verify the authenticity of the identification document or the person image. In this case, the reflection pattern can be compared, for example, with a reference pattern. Further, the reflection pattern may be understood as a binary encoding which may be decoded or decrypted using a cryptographic key.

However, according to one embodiment, the size of the test matrix can also be variable and depend, for example, on a person's date, a document date or a coding or an encryption of this data. FIG. 3 shows exemplary embodiments of a test matrix 301 with two rows and three columns, using the example of an occupancy of the first test matrix fields 105 with the first light-reflecting printing ink 106.

However, according to one embodiment, the check matrices 103 and 301 may be fixedly defined and have a same occupancy pattern for all faces of a document type with, for example, a monochrome representation, such as the first ink 106.

According to an embodiment, the size of the test matrix may be fixed or variable, while the test matrix fields have printing inks which are different in the predetermined wavelength range. This can be realized by the fact that the different printing inks reflect different light spectra.

FIG. 4 shows the test matrix 103 with an exemplary predefined pattern which is characterized by the plus signs, which is a light-reflecting Show ink, and with different inks. Thus, as illustrated in FIG. 4b, only the first test matrix fields 105 with the first printing ink 106, for example blue, can be used. The arrangement of the first pressure areas 105 results from the arrangement of the plus signs shown in FIG. 4a, which indicates an encoding or an occupancy of the matrix. This indicates in particular which test matrix field should be light-reflecting. In the exemplary embodiment illustrated in FIG. 4 d, the test matrix 103 comprises a third test matrix area 401, which is covered with a second ink 403. The second printing ink can be, for example, the printing ink green. This results in a different color pattern of the test matrix regions 105, 401, which indicates a color coding for the matrix assignment shown in FIG. 4a.

FIG. 4e shows an exemplary embodiment in which the third test matrix field 401 is covered with a third printing ink 405, for example red. For example, the first ink 106, the second ink 403, and the third ink 405 are configured to reflect light in different light spectra. For this purpose, the printing inks 106, 403, 405 can be provided with different light-reflecting pigments.

FIG. 5 shows the example of the test matrix 301 as well as the test matrix assignment shown in FIG. 5a with light-reflecting test matrix fields, which are marked with the plus sign, as well as the occupancy pattern shown in FIG. 5b using the example of the first test matrix field 105. In FIGS. 5c, 5d and 5e, different color patterns or color codes result for the different printing inks which can be used to check the authenticity of the person image 101.

The sizes of the matrices 103, 301 may be fixed or personalized and may be determined, for example, by a person's date, by a document date or by an encoding or encryption or hash value generation on the basis of the document's date.

According to one embodiment, the size of the test matrix may be predetermined, while the matrix assignment is monochrome or multicolor and corresponds to a coding. In FIGS. 6a to 61, the example of the first test matrix field 105 is different Assignments of the test matrix 103 shown, which have different patterns of the same printing ink, for example, the first ink 106 ,. The different assignments of the check matrix fields may be a result of a personalization of the check matrix 103 and may depend, for example, on a person's date or on a document date, as already described. However, the different assignments of the test matrix fields can be understood as an optically detectable code, for example a barcode or a multi-dimensional code, which can also be optically detected and decoded. The optically detectable code may, for example, encode a person's date or a document date or other information which, after decoding, may be compared with a reference date or reference information to verify the authenticity of the person's image 101.

Using the example of the test matrix 103, FIG. 7 shows different geometric and colored assignments of the test matrix fields with first test matrix fields 105 with the first printing ink 106 and, for example, third test matrix fields 401 with the printing inks 403 and 405. In addition to a geometric coding, a color coding, ie a further color coding Coding dimension, provided to verify the authenticity of the person image. For example, the first ink 106, the second ink 401, and the third ink 403 are transparent in the white light region.

The second test matrix fields 107 shown in FIGS. 6 and 7 are free of any printing ink. According to one embodiment, however, the second test matrix fields 107 may also be covered with the second printing ink 401 or the third printing ink 402.

However, according to one embodiment, the size of the check matrix itself may be variable and personalized, such that the number of rows and columns may be dynamic, such as a person's date, a document date, or encoding, encryption, or hashed based on the person's date and the document's date depend. 8 shows test matrices 103, 301 and 801 with different assignments of the test fields and different occupation patterns without a color coding using the example of the first test matrix region 105 with the first printing ink 106 and with the second test matrix fields 107, which are not reflective. FIGS. 8d, 8e show a 3 × 3 test matrix 801, while FIGS. 8f, 8g show a 3 × 4 test matrix 103. In this way, different test patterns, which are distinguished by light-reflecting test matrix fields, can be defined which, for example, form an optical code which can be decoded. As the number of light-reflecting test matrix fields increases, so does the coded information density. 9 shows test matrices whose sizes, ie their number of rows and columns and their assignments, are personified with light-reflecting test matrix fields and depend, for example, on a person's date, document date, encoding, encryption or hash value formation on the basis of the person's date or the document's date , In the FIGS. 9a to 9c test matrices 103 and 301 are shown, which have the arrangement of the light-reflecting test matrix fields 105, 401 with the printing inks 106, 403, 405 shown in FIG.

FIG. 9d shows a 2x4 test matrix 901, while FIGS. 9e and 9f show the 3x4 test matrix 803 with differently colored test matrix field assignments.

In this way it is possible to provide graphic and differently colored patterns, which can be understood and decoded as a graphic and colored code in order to check the authenticity of the person image. 10 shows a document reading device 1000 with an image recording device 1001, which is designed to record a photograph of a person image of an identification document, for example the person image 101, in a predetermined wavelength range, for example in the ultraviolet wavelength range. The document reader 1000 further includes a processor 1003.

The image pickup device 1001 may be an image camera, a line scanner, or a flat-panel scanner. The image recording device 1001 is designed, for example, to supply the image as image data in digital form to the processor 1003. The processor 1003 is configured to detect the test matrix having the first test matrix field and / or the third test matrix field, which is light-reflecting in the predetermined wavelength range, on the basis of the image data forming the photograph. In addition, the processor may be configured to reflect the different inks as stated above to detect color coding in the shot. The processor 1003 can further be configured to detect the arrangements of the light-reflecting test matrix fields or the third test matrix fields and to decode them as a geometric code, for example QR code, and compare the decoded information with reference information in order to verify the authenticity of the test object Capture person picture.

The document reader 1000 may further comprise a document support 1005 on which an identification document can be placed, which is not shown in FIG. The document reading device 1000 may further comprise a light source 1007, which is designed to illuminate the identification document with light in the predetermined wavelength range, for example to illuminate or to be illuminated for recording.

The document reader 1000 illustrated in FIG. 10 can be designed to check the authenticity of the person image 101 of the identification document 100 by decoding or decrypting the detected test matrix superimposed on the person image 101. According to a further embodiment, the document reading device 1000 may comprise a memory in which, for example, reference data, for example registered identification numbers or reference arrangements, are stored. Furthermore, a private or a public cryptographic key can also be stored in the memory in order to decode the arrangements of the reflective test matrix fields. The memory may also contain the decoding rule for decoding a graphic code. According to one embodiment, the document reader 1000 may further comprise a communication interface for retrieving reference arrays or reference data of the aforesaid kind or other reference data over a communication network from a remote server or for transmitting the detected arrays to the remote server for decoding or decryption and for a result the review or decoding or decryption performed by the reference server for verifying the authenticity of the identification document.

LIST OF REFERENCE NUMBERS

100 identification document

101 person picture

 103 test matrix

 105 first test matrix field

106 first printing ink

107 second test matrix field

109 Machine readable zone

301 test matrix

 401 third test matrix field

403 second printing ink

405 third printing ink

803 test matrix

 901 test matrix

 1000 document reader

1001 image recording device

1003 processor

 1005 document edition

1007 light source

Claims

1 . Identification document (100) with a person picture (101), wherein the

Person image (101) is superimposed on a test matrix (103, 803, 901), wherein the test matrix (103) has a first test matrix field (105) and a second test matrix field (107), wherein the first test matrix field (105) comprises a first printing ink (106). which is configured to reflect light in a predetermined wavelength range, and wherein the second test matrix array (107) is free of the first ink.

The identification document (100) of claim 1, wherein the second test matrix array (107) comprises a second ink, the first ink (104) and the second ink (106) being different spectra of the predetermined one

Wavelength range reflect or wherein the second ink (403) is transparent in the predetermined wavelength range.

The identification document (100) of any one of the preceding claims, wherein the test matrix (103) comprises a third test matrix field (401) or a plurality of third ones

Having test matrix arrays (401) with a second or third ink (403, 405), wherein the second ink (403) or the third ink (405) is configured to reflect light in the predetermined wavelength range, the first

Printing ink (104), the second ink (403) and the third ink (405) are adapted to reflect different spectra of the predetermined wavelength range.

The identification document (100) according to claim 2 or 3, wherein the first ink (106) is adapted to reflect light in the ultraviolet A wavelength range, wherein the second ink (403) is formed, especially in the ultraviolet B wavelength range or in the ultraviolet C wavelength range.

5. Identification document (100) according to claim 2, 3 or 4, wherein the

different inks (106, 403, 405) form a color coding of information, in particular a person's date or a document date.

6. identification document (100) according to any one of the preceding claims, wherein the respective printing ink (106, 403, 405) is transparent in the visible white light wavelength range light.

7. identification document (100) according to any one of the preceding claims, wherein an arrangement of the respective test matrix field (105, 107, 401) in the test matrix (103, 803, 901) of a person's date or a document date depend or by an encoding of a person's date or a document date is determined.

The identification document (100) of any one of the preceding claims, wherein the check matrix (103, 803, 901) has a number of columns and a number of rows, the number of columns and the number of rows being from a person's date or from a document's date depend on or by coding a

Person's date or a documentary date.

9. Identification document (100) according to one of the preceding claims, wherein the arrangement of the respective test matrix field (105, 107, 401) is determined by a binary or binarized person's date or by a binary or a binarized document date, or by a coding of a person's date or a

Document date is determined or is determined by an asymmetric or symmetric encryption or by a digital signature of a person's date or a document date or derivatives or is determined by a hash value of a person's date or a document date.

10. identification document (100) according to any one of the preceding claims, wherein the test matrix (103, 803, 901) forms a bar code or a multi-dimensional and optically detectable code, the code coded data, in particular a

Person data or a document date, provides.

1 1. An identification document (100) according to any one of the preceding claims, wherein the test matrix (103, 803, 901) is printed on a document body above the person image (101), or wherein the test matrix (103, 803, 901) is printed on a film which overlies the person image (101) arranged, in particular glued or laminated.

12. A method for producing an identification document with a person image, wherein the person image a test matrix with a first test matrix field and a second test matrix field overlaid, in particular by printing or sticking is superimposed, the first test matrix field having a first ink which is formed light in one reflect predetermined wavelength range, and wherein the second test matrix field is free of the first ink.

13. Document reader (1000) for detecting the authenticity of a

An identification document comprising a person image and a test matrix superimposed on the person image, wherein the test matrix has a first test matrix field and a second test matrix field

Test matrix field, wherein the first test matrix field comprises a first ink, which is adapted to reflect light in a predetermined wavelength range, and wherein the second test matrix field is free of the first ink. image recording apparatus (1001) for capturing a photograph of the person image in the predetermined light wavelength region; and a processor (1003) configured to detect in the receptacle the test matrix with the first test matrix field reflecting light in the predetermined wavelength range.

14. Document reader (1000) according to claim 13, with a light source (1007) which is designed to illuminate the identification document with light in the predetermined wavelength range, in particular in the infrared wavelength range or in the ultraviolet wavelength range, for the recording of the person image.

15. The document reading device (1000) of claim 13, wherein the processor is configured to detect an arrangement of the first test matrix field and an arrangement of a second test matrix field or a third test matrix field in the image of the person image, and the detected arrangement as a Barcode or multidimensional code to decode, decrypt or with a

Compare reference arrangement, or a color coding of the test matrix with Prüfmatrixfeldern, which different spectra of the predetermined Reflect wavelength range, detect and decode the detected color coding to capture the authenticity of the identification document.