WO2013156724A2 - Method and system for constructing a visual display comprising an image and a dynamic code - Google Patents

Abstract

The invention relates to a method for constructing a visual display (KK) comprising an image (I) and a dynamic code (CD) containing a piece of information relative to a predefined identifier (ID) referring to an electronic address (AE), the method comprising: a determination step (S1) consisting of determining the dimensions (L, l) of the image (I), a creation step (S2) consisting of creating a dot matrix (M) from the dimensions (L, l) of the image (I), a first generation step (S4) consisting of generating the dynamic code (CD) on the basis of the predefined identifier (ID), a conversion step (S6) consisting of converting the dynamic code (CD) into a first series of pixels (PIX1), and a construction step (S7) of constructing the visual display (KK), consisting of integrating said image (I) into an embedding area (Z0) of the dot matrix (M) and positioning the first series of pixels (PIX1) around the image (I) according to at least one first defined region (Z1) of the dot matrix (M). The invention also relates to the associated device.

Description

 METHOD AND SYSTEM FOR CONSTRUCTION

 OF A VISUAL COMPRISING AN IMAGE AND A DYNAMIC CODE Technical field

 The object of the present invention relates to the field of 2-dimensional codes, and more specifically to the field of matrix codes.

 The object of the present invention aims in particular to make more attractive and more secure the use of current matrix codes.

 The object of the present invention thus finds many applications particularly advantageous in the field of marketing, advertising and / or communication in general.

 Other advantageous applications are conceivable in the context of the present invention: the object of the present invention providing additional information and security level to any person wishing to access the data contained in the matrix code according to the present invention. The object of the present invention thus finds an advantageous application for example in the field of the fight against counterfeiting.

 By "matrix code" within the meaning of the present invention is meant throughout the present description which follows a 2-dimensional code containing digital information, this information being accessible by "scanning" said code with a communication device, of the type for example " Smartphone "or digital tablet, equipped with a means of capturing digital images. By "scanner" in the sense of the present invention, it is understood here to digitally acquire the matrix code in a digital video stream. It can thus be a digital acquisition of the type to acquire one or more digital images, or to acquire a digital video.

State of the art

There are several types of matrix code today: among these codes, there are notably "Flash Code", "QR Code", "Data Matrix", "Aztec code", "Maxi Code", etc. Current techniques for generating such codes provide good security and robustness; they also offer sufficient redundancy in the coding so that access to the information contained in these codes is ensured, even when the code is not correctly entered numerically or that code is corrupted.

 Nevertheless, the applicant has observed that none of the current codes has a contextual element: with the current solutions, it is impossible for a user to know precisely the origin of the matrix code that it wants to "scan".

 Matrix codes are now part of all advertising campaigns: they are found on all types of media: posters, magazines, commercial brochures, etc.

 However, when a person sees a matrix code, it was observed by the applicant that this person often hesitates to "scan" this code with his "Smartphone", this for fear of accessing an unwanted website or receive a computer virus.

 Indeed, there exists in current matrix codes no element allowing to establish a link between the code and the product or the mark represented on the support.

 This code is also presented in a corner of the poster in a small format. Consequently, in front of this code formed solely of pixels and without any contextual information, the person is reluctant to seize his digital device to "scan" the code; This is a psychological fear quite understandable in the face of such a code without information readable or understandable by a single user.

 This behavior of the user, who is not yet accustomed to "scan" this type of code, is reproduced in many other situations, and represents a brake for the development of this technology which aims on the contrary to provide the the user a maximum of information about the product or brand.

 This represents a major disadvantage in this area.

It is also easy for malicious people to promote counterfeiting by sending consumers directly to a merchant site. counterfeit products. Current matrix codes do not assure consumers that they will be returned to the "official" site of the product presented.

Object and Summary of the Present Invention

 One of the objectives of the present invention is to improve the situation described above by enriching the current offer while ensuring equivalent or even higher levels of security.

 For this purpose, the object of the present invention relates to a method of constructing a visual comprising an image and a dynamic code containing information relating to a predetermined identifier referring to an electronic address or digital information.

 The joint presence of an image included in the visual and of a dynamic code is characteristic of the present invention and makes it possible to establish the link between the visual to "scan" and the information contained in the dynamic code. We can speak here of an image called contextualization.

 Optionally, the method according to the present invention comprises a preliminary acquisition step of acquiring this image and this electronic address.

 This step can be carried out for example by a subscriber to the service or a customer who wishes to build a visual, and who has a contextualization image and a relative email address for example to its website.

 By e-mail address within the meaning of the present invention, it is necessary to understand throughout the description that follows a URL address to access a website, a phone number, an e-mail address, or any other digital information to access to a communication service.

 This electronic address may consist of the information relating to the coordinates of a person, this being possible in particular for a use of the present invention in the context of an electronic business card which allows to digitally access the coordinates of the cardholder.

In an advantageous variant, the method according to the present invention comprises an assignment step during which the electronic address is assigned to a predetermined identifier. Advantageously, a database stores these information. This assignment step can be performed indifferently at any time in the process.

 Following these two optional steps, the method according to the present invention comprises a determination step during which the dimensions of the image are determined.

 The information relating to the dimensions of the image makes it possible, as can be understood in the following, to create a visual according to the image, and more precisely according to these dimensions.

 Optionally, a comparison of these dimensions such as a ratio or difference is calculated.

 Then, the method comprises a creation step during which a matrix of points is created, this according to the dimensions of the image or the results of this comparison.

 We note here that this step makes it possible to create a matrix which serves as a basis for the construction of the visual.

 According to the present invention, this matrix has predetermined areas according to the dimensions of the image such that the image can cover a large part of the surface of the visual: it is provided according to the present invention that the image covers at least 35 % of total visual area

 Advantageously, the method according to the present invention comprises a first generation step during which the dynamic code is generated according to the predetermined identifier.

 Preferably, this dynamic code is a binary code.

 Alternatively, this dynamic code can also be a hexadecimal code. This code is preferably generated from a predetermined encoding table.

 A particular embodiment of this code generation step is described in detail in the following description. Of course, this mode is presented as an example; other equivalent code generation modes may be envisioned within the scope of the present invention.

Advantageously, the method according to the present invention comprises a conversion step which consists of converting this dynamic code into a first series of pixels. This conversion is performed in particular from a predetermined conversion table. This first series of pixels is intended to be positioned in the matrix to form the visual: thus, by "scanning" the visual, the digital device detects and reads this code, then decrypts it to access the information it contains. , namely the information relating to the identifier.

 Advantageously, the method according to the present invention comprises a visual construction step. In this step, the image is embedded in a dot matrix overlay area, and the first set of pixels is positioned around the image according to at least a first determined area of the dot matrix.

 As mentioned above, this embedding area covers a preponderant surface of the matrix (at least 35% of the area of the matrix) so that the image appears distinctly; this makes it possible to reassure the consumer wishing to "scan" the visual.

 Thanks to the succession of these technical steps, characteristic of the present invention, the method described above makes it possible to construct a visual which comprises on the one hand a so-called contextualization image, and on the other hand a dynamic code containing relative information. a predetermined identifier referring to an electronic address, or digital information.

 Thus, in the field of advertising for example, when such a visual is presented on an advertising medium, the person who consults this medium immediately recognizes the representative image of the product or the proposed brand, he does not hesitate in this case to seize his digital camera of the "Smartphone" type to "scan" this visual. His device, which is able to decrypt the dynamic code after loading a suitable application, can obtain the email address to access for example the website of the product or brand in question.

 The fact that an image is visible on such a visual reassures the consumer, which is not the case of current matrix codes.

The technology developed here in the context of the present invention thus makes it possible to modify the behavior of the consumer with respect to the matrix codes: indeed, as explained above, the current matrix codes are not used for a satisfactory way, especially given the consumer's reluctance to deal with all his pixels. The present invention overcomes this problem.

 Advantageously, the method according to the present invention comprises a second generation step which consists in generating an error correction code according to the dynamic code.

 The error correction code is a code that advantageously ensures the integrity of the dynamic code when read by a digital device.

 Preferably, this error correction code is a binary code.

 Alternatively, this error correction code is a hexadecimal code. Advantageously, the error correction code generated during the second generation step is a Reed-Salomon code based on a Galois body.

 The use of such a code makes it possible to obtain very good results in terms of robustness and redundancy, it makes it possible in particular to reconstruct the dynamic code in its entirety even if an error occurred during the transmission or the capture of the code, or when the visual is deteriorated.

 Advantageously, the conversion step furthermore comprises the conversion of the error correction code into a second series of pixels, and the visual construction step comprises the positioning of this second series of pixels around the image according to FIG. minus a second determined area of the dot matrix.

 Thus, there is obtained a visual comprising the image as such, as well as the first and second series of pixels which relate respectively to the dynamic code and the error correction code.

 Advantageously, the visual construction step comprises, depending on the dimensions of the image, the addition of a third series of randomly generated pixels.

It is indeed possible that the image has a size too large for the first and second series of pixels to cover the areas dedicated to them. In this case, the method provides this step, called "stuffing", during which randomly generated pixels are added. Advantageously, the creation step comprises the insertion of at least two locator targets near at least two of the successive corners of the matrix of points, this step is done according to the dimensions of the image.

 It will be understood that for small images, the matrix comprises two or three registration targets, and for large images, the matrix comprises three or even four registration targets.

 Advantageously, during the creation step, the dot matrix is created in such a way that it comprises a reading zone connecting the successive registration targets and comprising an alternation of black and white pixels.

 Advantageously, the method according to the present invention comprises a masking step which consists in applying a mask to all the pixels of the matrix, except in particular those of the image. This mask is a mathematical mask to add an extra layer of encryption to not access the code itself.

 Moreover, depending on the codes generated, the matrix may be too homogeneous: for example, when it has large black areas (black pixels), or large white areas (white pixels).

 This situation is not desirable because it makes reading difficult. The masking step overcomes this problem by distributing the best black and white pixels in the matrix, to obtain a visual apt to be better decrypted.

 Correlatively, the object of the present invention relates to a computer program which includes instructions adapted for the execution of the steps of the method of provisioning as described above, this in particular when said computer program is executed. by a computer.

 Such a computer program can use any programming language, and be in the form of a source code, an object code, or an intermediate code between a source code and an object code, such as in a partially compiled form, or in any other desirable form.

Similarly, the subject of the present invention relates to a computer-readable recording medium on which a computer program is recorded. including instructions for performing the steps of the provisioning method as described above.

 On the one hand, the recording medium can be any entity or device capable of storing the program. For example, the medium may comprise storage means, such as a ROM, for example a CD-ROM or a microelectronic circuit-type ROM, or a magnetic recording means, for example a diskette of the type " floppy says "or a hard drive.

 On the other hand, this recording medium can also be a transmissible medium such as an electrical or optical signal, such a signal can be conveyed via an electric or optical cable, by conventional radio or radio or by self-directed laser beam or by other ways. The computer program according to the invention can in particular be downloaded to an Internet type network.

 Alternatively, the recording medium may be an integrated circuit in which the computer program is incorporated, the integrated circuit being adapted to execute or to be used in the execution of the method in question.

 The subject of the present invention also relates to a computer device for constructing a visual. More specifically, the computer device according to the present invention comprises computer means for constructing a visual comprising an image and a dynamic code containing information relating to a predetermined identifier referring to an electronic address or digital information.

 According to the present invention, the device advantageously comprises:

 determining means which is configured to determine the dimensions of the image,

 a creation means which is configured to create a dot matrix according to the dimensions of the image,

first generation means which is configured to generate the dynamic code according to the predetermined identifier; preferably, this dynamic code is a binary code or possibly a hexadecimal code, conversion means which is configured to convert the dynamic code to a first series of pixels, and

 a visual construction means which is configured in particular for, on the one hand, integrating the image into an inlay area of the matrix of points and, on the other hand, positioning the first series of pixels around the image according to at least a first determined area of the dot matrix.

 Thus, thanks to the arrangement of these technical means, characteristic of the present invention, the device allows the construction of a visual comprising an image and a dynamic code.

 By seeing a visual with an image, people immediately know that the visual directly relates to the image that it contains, the image of a product or a brand for example, and in these circumstances, these people are more reluctant to "scan" the visual to capture and decrypt with the help of a digital device of the "Smartphone" type the dynamic code it contains.

 Advantageously, the device according to the present invention comprises a second generation means which is configured to generate an error correction code according to the dynamic code.

 Preferably, this second generation means is configured in such a way that the error correction code is a binary code. This code can also be generated in such a way that it consists of a hexadecimal code.

 Advantageously, the second generation means is further configured such that the error correction code is a Reed-Salomon code based on a Galois field.

 As mentioned above, such a code allows the reconstruction of the dynamic code if necessary.

In an advantageous variant embodiment, the conversion means is configured to convert the error correction code into a second series of pixels. In this variant, the visual construction means is configured to position the second series of pixels around the image in at least a second determined area of the dot matrix. These different means are specific image processing means configured for this purpose.

 Advantageously, the visual construction means is configured to add, according to the size of the image, a third series of randomly generated pixels, this to allow a "stuffing" of pixels if necessary.

 Preferably, the means of creation is configured to insert, as a function of the dimensions of the image, at least two locating targets near at least two of the successive corners of the matrix of points.

 Advantageously, the means of creation is configured so that the matrix of points comprises a reading zone connecting the successive identification targets and comprising an alternation of black and white pixels.

 According to a preferred variant, the device according to the present invention comprises a masking means which is configured to apply a mask to all the pixels of the matrix, except in particular those of the image.

 Advantageously, the device according to the present invention comprises an acquisition means which is configured to acquire the image and the electronic address.

 Advantageously, the device according to the present invention comprises an assignment means which is configured to assign the predetermined identifier to the electronic address.

 Thus, the object of the present invention, by its different functional and structural aspects, allows the construction of a visual that makes the current matrix codes more attractive. Indeed, the visual obtained according to the present invention includes an image having a psychological effect on the consumer who is therefore reassured by seeing that the visual that he is about to "scan" with his digital camera is in close relationship with the content of the image.

The visual constructed according to the present invention also offers a level of encoding and redundancy equivalent to, or superior to, that of the matrix codes of the state of the art. Brief description of the attached figures

 Other characteristics and advantages of the present invention will emerge from the description below, with reference to FIGS. 1 to 3, which illustrate an exemplary embodiment without any limiting character and on which:

 - Figure 1 schematically shows a computer device for the construction of a visual according to an advantageous embodiment;

 FIGS. 2A to 2C show schematically an example of the various intermediate steps of construction of a visual according to the present invention; and

 FIG. 3 represents a flowchart illustrating the method of reconstructing a visual according to an advantageous exemplary embodiment. Detailed description of an embodiment of the invention

 A computing device and method, in accordance with an advantageous exemplary embodiment of the present invention, will now be described in the following with reference to Figures 1 to 3.

 As a reminder, making the current matrix codes more attractive is one of the objectives of the present invention. More precisely, contextualizing the matrix code so that the consumer no longer hesitates to "scan" the code presented to him is one of the objectives of the present invention.

 As explained above, the Applicant has found that the current matrix codes, which are essentially essentially black and white pixels encoding an identifier, do not encourage the consumer to enter his "Smartphone".

 In fact, these codes do not visually contain the information making it possible to establish the link with its content, that is to say the information it returns.

 The concept underlying the present invention is therefore to integrate an image in a matrix code, such a so-called contextualization image, in particular to reassure the consumer.

One of the technical difficulties to be solved in the face of such a problem is not to lose redundancy in the code so that when one "scans" the code, one obtains the information sought for sure. First tests were performed on the "QR Code" by the plaintiff to insert such an image. Nevertheless, these tests proved very inconclusive.

 Indeed, this type of code exploits mainly the redundancy.

 Thus, with a code having 30% redundancy (the maximum possible for the "QR Code"), it is possible to insert an image on only 30% of the total surface of the code.

 This solution is not conceivable since it would amount to imposing the format of the image for the construction of the code.

 Moreover, if this redundancy is removed in the code to insert the image over a large area, it is then necessary that the code is "scanned" under optimal conditions and without any defect, otherwise the code can not be decrypted.

 Without affecting the redundancy, the insertion of an image into a conventional matrix code implies an exponential increase in the size of the code, which is very unsightly and even contrary to the principle of the matrix code which must generally remain discreet.

 The reasons for these drawbacks lie mainly in the fact that originally the matrix codes are codes intended for traceability and logistics (especially in the automotive industry for "QR Code"), and are not intended to integrate an image into post-processing.

 The underlying idea here is to build pre-processing a matrix code around an image. This pretreatment construction, which is characteristic of the present invention, is presented in detail in the description which follows.

 The construction of such a visual K (including image and matrix code) is performed by a particularly innovative computer device 100.

 First, it should be noted that in the example described here, this device 100 includes a database DB which contains a plurality of predetermined IDs IDs.

In the example described here, an ID identifier consisting of 15 characters consisting of uppercase, lowercase letters, and numbers is used. This allows a very large number of possible combinations. The example described in the following description is based on the following identifier ID: "Ak6Fm45Yp2hQ3SH".

 According to the invention, the person who accesses the service (that is to say the person who wishes to communicate on his product) submits during a preliminary step of acquisition S0 a digital image I representative of his product or his Mark. It may be for example the logo of his company or a picture of the product he wants to sell or at least on which he wishes to communicate.

 This person submits at the same time an E-mail address AE of his choice: the one providing the information on which he wants to communicate.

 In the example described here, this is the address of a company's website.

As mentioned above, it may be another communication address allowing access to information.

 This step S0 is possible thanks to the acquisition means MO of the device 100.

Then, the identifier ID and the electronic address AE are, during an assignment step S3, associated with each other, this through an assignment means M3.

 This assignment, as mentioned above, can occur at any time in the process. In the same way, the AE email address can also be changed at any time.

 This ID / AE information is stored in a DB database. By associating the electronic address AE with the identifier ID, it is understood here that the goal is that the person obtaining the information relating to the identifier ID directly accesses the website on which the email address AE returns by interrogating the database. DB data.

 Allowing the preprocessing construction of a code around an image I to obtain a visual K is one of the objectives of the present invention.

 In the example described here, during a first generation step S4, a dynamic code CD is generated based on this identifier ID. The code CD therefore includes the information allowing access to the website relating to the address AE.

 In the example described, the generation of the code CD takes the following form:

The characters that make up the identifier are first converted to positive integers according to a clean table. This table takes for example the following form: From "A" to "Z": from 65 to 90.

 From "a" to "z": from 97 to 122.

 According to this table, the identifier "AkGFmOPYpVhQBSH" becomes the following integer sequence: "65 - 107 - 71 - 70 - 109 - 79 - 80 - 89 - 112 - 86 -104 - 81 - 66 - 83 - 72"

 According to this table, this series of integers is then converted into 8-bit coded bits, ie: "01000001-01101011-01000111-01000110-01101101- 01010001-01010000-01011001-01110000-01010110-01101000-01010001-01000010- 01010011-01001000 »

 This string of 15 bits is finally transformed into a string of 12 bits coded on 10 bits, ie: "0100000101-1010110100-0111010001-1001101101- 0101000101-0100000101-1001011100-0001010110-0110100001-0100010100- 0010010100-1101001000"

 This chain constitutes in the example described here the dynamic code CD within the meaning of the present invention.

 It should be understood that the code generation presented above is only an advantageous embodiment of the present invention, and is not limiting in any way. Other encoding variants are provided.

 It can be noted here that, if the string of binary numbers obtained is not large enough to fill the zone that is intended for it, then it is possible to add so-called "jamming" bits generated randomly to obtain a string with the number of bits sufficient.

 This bit string is obtained in the present invention by means of a first computer generation means M4 configured for this purpose.

 Once this dynamic code CD obtained, the method comprises a second generation step S5 in which a CC error correction code is generated, this generation is a function of the dynamic code CD.

In the example described here, this error correction code CC is obtained by building a Galois field to realize the Reed-Salomon algorithm and obtain a so-called Reed-Salomon code. This code of Reed-Salomon is a correction code based on the body of Galois whose principle is to build a formal polynomial from symbols to be transmitted and to oversample it. The result is then sent, instead of the original symbols. The redundancy of this oversampling allows the receiver (here for example a "Smartphone") to reconstruct the polynomial even if there were errors during the transmission.

 In the example described here, the error correction code CC is formed by a 10-bit block, this generation of the code CC is carried out by means of a second generation means M5 adapted for this purpose.

 In parallel with these steps S4 and S5 generating CD and CC codes, the device 100 according to the present invention determines the dimensions L and 1 of the image I, this during a determination step S1 and by means of determination means Ml.

 The determination means M1 may also be able to compare the dimensions L and 1 by calculating for example a 1 / L ratio or an L-1 comparison.

 In the example described here, according to these dimensions L and 1 and possibly the results of this comparison, the creation means M2 creates, during a creation step S2, a matrix M.

 This matrix M is in the form of, for example, an array of 2-dimensional booleans (0 = false = white and 1 = true = black).

 It is possible to provide an image optimizer configured so that the acquired digital image I has an even number of pixels. It is also possible to provide means (not shown here) to resize the image I, especially if it is too large, that is to say for example if it has too many pixels.

 In the example described here, and as illustrated in FIG. 2A, the creation means M2 also makes it possible, as a function of the dimensions L and 1, to generate and position four target targets T, or "Target", in a zone corresponding to each of the corners of the matrix M. These "Targets" T advantageously facilitate the reading by the "Smartphone" codes CD and CC: they allow to delimit the visual in space.

In the example described here, and as illustrated in FIG. 2A, this means of creation M2 makes it possible moreover to insert a read zone Z4 connecting the successive identification targets T and comprising an alternation TP, called "Timing pattern", of black and white pixels. This "Timing pattern" makes it possible to promote reading and decoding, especially when the visual KK is too deteriorated: it indeed determines a reading axis for the decoder.

 Thus, as illustrated in FIG. 2A, the structure which serves for the construction of the visual KK is obtained thanks to this means of creation M2.

 It should be noted that the comparison of the dimensions L and 1 of the image I makes it possible to determine the type of matrix M to be provided. Indeed, if for example, the ration 1 / L is equal to 1: we must provide a square matrix. If the ratio 1 / L is strictly greater than 1 or strictly less than 1, a matrix of rectangular shape (oriented in the direction of the height or in the direction of the width) must be provided. An equivalent determination for calculating a difference is also provided.

 It is then a question of constructing this visual KK so that it notably integrates the image I, the dynamic code CD and the error correction code CC.

 For this purpose, during a conversion step S6 carried out by a conversion means M6, the previously obtained CD and CC codes are respectively converted into a first PIX1 and a second PIX2 series of pixels, each of which is intended to be positioned on a number of pixels. Specific zones ZI and Z2 of the matrix M. This positioning of the pixel series PIX1 and PIX2 is along the Timing pattern TP on either side of it according to a distribution specific to the developed technology.

 By way of illustration, it may for example be provided with a block distribution of 10 bits (or 10 pixels) which is done according to the following table:

0 5

 1 6

 2 7

 3 8

4 9 Thus, with the binary number encoded on the following 10 bits "1010011101", the following distribution is obtained:

Of course, this example is taken for illustrative purposes only.

 The decoder implemented in the "Smartphone" therefore knows this table, and when it detects and reads the code, it is able to rebuild the initial code according to this table to find the binary number.

 Once this distribution has been made, the bits corresponding to pixels PIX1 and PIX2 are positioned on the respective zones Z1 and Z2 which are dedicated thereto, this during a construction step S7.

 As mentioned above, there is also provided a "stuffing" with a series of pixels PIX3 according to a third zone Z3 when the dimensions L and 1 of the image I require it. These PIX3 pixels are generated randomly.

 It is also possible to provide the positioning of a codeword codeword indicating the number of pixels to read (not shown here); this makes it easier to read the pixels PIX1 and PIX2 by the decoder.

 Then, again during this construction step S7, the image I is integrated in the Z0 inlay zone which is dedicated to it (see FIG. 2B).

 These various steps of construction of the visual K are implemented by a specific construction means M7 such as a computer module image processing.

As mentioned above, it is possible that, depending on the CD and CC codes, the visual KK obtained has one or more surfaces of pixels that are too homogeneous. (black or white surface); such surfaces are difficult to detect and decipherable, which makes the visual K inefficient.

 In this case, a mask MA is applied in particular to zones ZI and Z2 to "mathematically" mix these pixels PIX1 and PIX2 and make them more heterogeneous. This masking performed during a step S8 by a mathematical masking means M8 also makes the encoding undetectable; indeed, without the prior knowledge of the mathematical mask used, it is impossible to decipher the code.

 It can be noted here that this masking is not applied to the image I as such, nor to the "Timing pattern" TP, nor to the "Codeword" or "Targets" T.

 An example of a visual KK comprising an image I and a first and second series of "masked" pixels PIX1 and PIX2 obtained according to the construction method of the present invention is illustrated in FIG. 2C.

 The device 100 also comprises an editing means M9 for editing the visual KK, such an edition can do this directly on an advertising medium.

 By "scanning" the KK display illustrated in FIG. 2C, it is possible to directly access the website relating to the electronic address AE. This is possible by assigning this AE address with a predetermined identifier ID and stored in a database DB administered by the computing device 100 or by an independent system located on a remote server and containing the database DB.

 More specifically, by "scanning" with a device of the "Smartphone" type containing a digital image sensor and the appropriate decryption software (via, for example, an integrated software or a specific application), the device decrypts the visual KK to obtain the information relating to the identifier ID. Through the communication means of the "Smartphone", it directly queries the database DB to obtain the email address AE corresponding to the identifier ID.

Given the structure of such a visual KK and the encoding algorithms used, the visual KK has very good performance: it is possible to decrypt the dynamic code CD and access the address AE whatever the conditions of capture of the visual KK, this even when the visual KK is altered or truncated, this notably thanks to the redundancy and the error correction code CC.

 By virtue of this construction method allowing a preprocessing construction of a visual KK comprising an image I and a dynamic code CD (or matrix code), the subject of the present invention makes it particularly possible for the communication industry and marketing an innovative service allowing the custom construction of KK visuals whatever the image I input, while ensuring good security and good redundancy of the code.

 This technology is also particularly suitable for combating counterfeiting by limiting the proliferation of merchant sites offering counterfeit products.

 This construction of the visual KK by the computer device 100 according to the present invention is possible by a succession of technical steps executed by a computer program PG contained on a recording medium CI included in the device 100 and making it possible to control each of the means of this device.

 It should be observed that this detailed description relates to a particular embodiment of the present invention, but in no case this description is of any nature limiting to the subject of the invention; on the contrary, its purpose is to remove any imprecision or misinterpretation of the claims that follow.

Claims

A method of constructing a visual (KK) comprising an image (I) and a dynamic code (CD) containing information relating to a predetermined identifier (ID) returning to an electronic address (AE),

the process comprising the following steps:

 a determination step (SI) of determining the dimensions (L, 1) of the image (I),

 a creation step (S2) of creating a matrix of points (M) according to the dimensions (L, 1) of the image (I),

 a first generation step (S4) of generating the dynamic code (CD) according to the predetermined identifier (ID); - a converting step (S6) of converting the dynamic code (CD) into a first series of pixels (PIX1), and

 a step of constructing (S7) the visual (KK) consisting in particular of integrating said image (I) in an area of incrustation (Z0) of the matrix of points (M) and positioning the first series of pixels (PIX1) around the image (I) according to at least one determined first zone (ZI) of the matrix of points (M).

2. Method according to claim 1, characterized in that it comprises a second generation step (S5) of generating an error correction code (CC) according to the dynamic code (CD).

3. Method according to claim 2, characterized in that the error correction code (CC) is generated in such a way that this code (CC) is a Reed-Salomon code based on a Galois body.

4. Method according to claim 2 or 3, characterized in that the conversion step (S6) comprises the conversion of the error correction code (CC) into a second series of pixels (PIX2), and that the construction step (S7) of the visual (KK) comprises positioning the second series of pixels (PIX2) around the image (I) according to at least one determined second zone (Z2) of the matrix of points (M).

5. Method according to any one of claims 1 to 4, characterized in that the step of construction (S7) of the visual (K) comprises, depending on the dimensions (L,

1) of the image (I), the addition of a third series of pixels (PIX3) generated randomly.

6. Method according to any one of claims 1 to 5, characterized in that the creation step (S2) comprises, depending on the dimensions (L, l) of the image (I), the insertion of at least two locating targets (T) near at least two of the successive corners of the dot matrix (M).

7. Method according to claim 6, characterized in that, during the creation step (S2), the matrix of points (M) is created in such a way that it comprises a reading zone (Z4) connecting the targets tracking (T) successive and comprising an alternation (TP) of black and white pixels.

8. Method according to any one of claims 1 to 7, characterized in that it comprises a masking step (S8) of applying a mask (MA) to all the pixels of the matrix (M), except especially those of the image (I).

9. Method according to any one of claims 1 to 8, characterized in that it comprises a prior step of acquisition (S0) of acquiring said image (I) and said electronic address (AE).

10. The method of claim 9, characterized in that it comprises an assignment step (S3) of assigning the predetermined identifier (ID) to said electronic address (AE).

A computer program (PG) having instructions adapted for performing the steps of the method according to any one of claims 1 to 10 when said computer program (PG) is executed by a computer.

A computer-readable recording medium (CI) on which a computer program (PG) is recorded including instructions for carrying out the steps of the method according to any one of claims 1 to 10.

13. Computer device (100) for constructing a visual (K) comprising an image (I) and a dynamic code (CD) containing information relating to a predetermined identifier (ID) returning to an electronic address (AE), the device (100) comprising:

 determining means (M1) configured to determine the dimensions (L, 1) of the image (I),

 a creation means (M2) configured to create a matrix of points (M) according to the dimensions (L, 1) of the image (I),

 first generation means (M4) configured to generate the dynamic code (CD) according to the predetermined identifier (ID),

conversion means (M6) configured to convert the dynamic code (CD) into a first series of pixels (PIX1), and

 a means of construction (M7) of the visual (KK) configured to integrate said image (I) in a zone of incrustation (Z0) of the matrix of points (M) and to position the first series of pixels (PIX1) around of the image (I) according to at least one determined first zone (ZI) of the matrix of points (M).

14. Device (100) according to claim 13, characterized in that it comprises a second generation means (M5) configured to generate an error correction code (CC) according to the dynamic code (CD).

Device (100) according to claim 14, characterized in that the second generating means (M5) is configured such that the error correction code (CC) is a body-based Reed-Salomon code. from Galois.

Device (100) according to claim 14 or 15, characterized in that the conversion means (M6) is configured to convert the error correction code (CC) into a second series of pixels (PIX2), and the construction means (M7) of the visual (KK) is configured to position the second series of pixels (PIX2) around the image (I) according to at least one determined second zone (Z2) of the matrix of points ( M).

17. Device (100) according to any one of claims 13 to 16, characterized in that the means of construction (M7) of the visual (KK) is configured to add, depending on the size (L, 1) of the image (I), a third series of pixels (PIX3) generated randomly.

18. Device (100) according to any one of claims 13 to 17, characterized in that the means of creation (M2) is configured to insert, according to the dimensions (L, 1) of the image (I), at least two locating targets (T) near at least two of the successive corners of the dot matrix (M).

19. Device (100) according to claim 18, characterized in that the creation means (M2) is configured so that the matrix of points (M) comprises a reading zone (Z4) connecting the successive registration targets (T). and comprising an alternation (TP) of black and white pixels.

20. Device (100) according to any one of claims 13 to 19, characterized in that it comprises a masking means (M8) configured to apply a mask (MA) to all the pixels of the matrix (M ), except in particular those of the image (I).

21. Device (100) according to any one of claims 13 to 20, characterized in that it comprises an acquisition means (MO) configured to acquire said image (I) and said electronic address (AE).

22. Device (100) according to claim 21, characterized in that it comprises an assignment means (M3) configured to assign the predetermined identifier (ID) to said electronic address (AE).