FR2986354A1 - Method for generating linear global two-dimensional code i.e. quick response code, involves encoding data in binary form from values defined in lookup table and translation value, and generating set of symbols - Google Patents

Abstract

The method involves configuring parameters of a data to be encoded, the size of linear global two-dimensional code i.e. quick response (QR) code, and the volume of coding data, where the code is printed on a support (20). The data is encoded in binary form from values defined in a lookup table and a translation value. A set of symbols is generated, where each symbol includes a column of dots having a color, a shape and a size, a line (21) forming a header, a row with encoded binary data, and a line forming a foot. The symbols from the set of symbols are juxtapositioned. An independent claim is also included for a computer program for generating a linear global two-dimensional code.

Description

FIELD OF THE INVENTION [0001] The invention relates to the field of global two-dimensional codes called 2D codes, in particular printable on a physical medium. In the context of the present application, DOT will be understood to mean an elementary information surface, generally binary, on any physical medium. This surface can have various shapes: rectangular, square, round etc. ; a color and a size. STATE OF THE PRIOR ART [0003] There are numerous two-dimensional (2D) codes called "global" or "matrix" codes, which are images created from an algorithm. The best known and most used in Europe is Datamatrix. His Asian counterpart is the QR Code. [0004] 2D codes are based on elementary binary surfaces. The coded information is then represented as bits. All these 2D codes are created using a software called "generator" that globally encodes a string of characters according to various parameters (redundancy rate, dots size. "). to add one or more characters, the industrial 2D codes impose an integration of the addition with a reissue of the new set regardless of the volume of the addition. [0006] The main form of all these codes is square. The size depends on the number of characters to be encoded The increase in the number of characters to be encoded does not have a strictly linear effect on the size of the code The increase in the size of the 2D code This means that the printing surface is not directly proportional to the amount of coded information. [0008] However, a 2D code increases significantly in height and in length with If this feature can be adapted to individual uses, it becomes very cumbersome or even unusable in a document with a rigorous layout and the available surface is rare: a marketing letter, an invoice, a contract, a label, newspaper, etc. One of the major drawbacks of these 2D codes lies in the fact that they integrate varying levels of security through the introduction of redundancy of information in several parts of the code to ensure its integrity. in case of partial destruction. The redundancy rate of a 2D code is usually configurable. If the code degradation is greater than this redundancy rate, no data is read. These matrix type codes require digital image capture technology (and not a simple read beam). These global 2D codes do not provide any simple tool for describing the data to be coded, i.e. for classifying data by type (semantics), and organization (syntax). They only provide information that is weakly structured and restricts its exploitation by the receiver. They are limited by their structure to very simple applications where the structure of the data is known to character: incrementation of numbers, association of a number to a web address, coding of low semantic value strings, etc. Another disadvantage of these 2D codes is that it is difficult to mix different types of symbols within the same structure, except by mentioning, for example, the different fields represented by private tags. Another major disadvantage of these 2D codes, such Datamatrix or QR Code, lies in the fact that for use in the context of document certification, for example, their morphology does not allow to easily adapt them to any shape and size of printing surface. In addition, their limited capacity does not allow the integration of a large amount of data. SUMMARY OF THE INVENTION [0014] The invention aims to remedy all or some of the disadvantages of the state of the art identified above. The invention offers a solution that has the advantage of allowing the generation of a global two-dimensional code having a linear morphology, an unlimited capacity, allowing a simple modification or insertion of new data, 25 supporting any type of data and secure . For this purpose, one aspect of the invention relates to a method for generating a linear global two-dimensional code comprising the following steps: configuration of parameters relating to a data mapping table to be coded, to the dimensions of the code linear global two-dimensional, to the volume of data to be encoded; encoding data in binary form from values defined in the correspondence table and said translation value; generating a first set of symbols in which each symbol comprises: at least one column of DOTs, each DOT comprising a color, a shape and a size; at least one line forming a header; a plurality of lines comprising the coded bit data; and at least one line forming a foot; juxtaposition of the symbols of the first set of symbols. Such a method has the advantage of allowing the generation of a global linear two-dimensional code whose capacity is unlimited by the juxtaposition of the symbols representing the data to be encoded. It is possible to juxtapose as many symbols as necessary. The shape of this code is linear, and this code is thus suitable for any type of layout on physical or electronic media, for example by insertion in invoices or faxes. In addition, such a generation method provides integration of an addition of data, regardless of the type of data, without necessarily having to generate all the code again. Indeed, all types of symbols can be juxtaposed without prior format declaration since each symbol codes its type. According to particular embodiments: the configuration step comprises the configuration of parameters relating to a translation value; the size of the DOTs is a function of the ratio of the volume of data to be encoded on the dimensions of the global linear two-dimensional code. Such a characteristic has the advantage of making it possible to size the global linear two-dimensional code as a function of a location on which it can be deposited; the configuration step comprises the definition of data relating to a redundancy calculation. the method further comprises a step of encoding the data relating to a calculation of redundancy in binary form; the method further comprises: a step of generating a second set of symbols called redundancy symbols, each symbol of the set comprising at least one column of DOTs, each DOT comprising a color, a shape and the size; at least one line forming a header; a plurality of lines comprising the binary data relating to a redundancy calculation and at least one line forming a foot; a juxtaposition step of the second set of symbols following the first set of juxtaposed symbols; the method further comprises: a step of generating a third set of symbols called redundancy symbols, each symbol of the set comprising at least one column of DOTs, each DOT comprising a color, a shape and the size; at least one line forming a header; a plurality of lines comprising the binary data relating to a redundancy calculation and at least one line forming a foot; a step of inserting symbols of the third set between symbols of the first set of juxtaposed symbols; the method further comprises an additional step of printing the code, the printing being done on at least one line; the printing step comprises a step of calculating the number of lines as a function of the size of the DOTs, the volume of coded data and the dimensions of the overall linear two-dimensional code. Such a feature has the advantage of ensuring that the printing area will be proportional to the amount of information to be encoded. the juxtaposition of the symbols of at least one of the sets of symbols is carried out so as to define a general form of said code for an orientation and a read direction suitable for carrying out a step of decrypting the data by an optical reader; the dimensions of the overall two-dimensional linear code correspond to the surface of a display area of a medium on which said code is capable of being printed. The invention also relates to a global linear two-dimensional code composed of a juxtaposition of a set of symbols, each symbol comprising at least one column of DOTs, such that the size of the DOTs is a function of the ratio of the volume of the data to be encoded and dimensions of the overall linear two-dimensional code. The invention also relates to a computer program comprising instructions for the execution of the steps of the method of generating a global linear two-dimensional code according to the invention when the program is executed by means of data processing. a computer device. BRIEF DESCRIPTION OF THE FIGURES [0022] Other features and advantages of the invention will emerge on reading the description which follows, with reference to the appended figures, which illustrate: FIG. 1, the main steps enabling the generation of a code linear global two-dimensional; FIG. 2, the main steps of the coding of the information, the generation of the first set of symbols and the juxtaposition of the symbols of the first set of symbols; FIG. 3, a global linear two-dimensional code generated by the method according to one embodiment of the invention; FIG. 4, the printing of a global linear two-dimensional code on a support according to one embodiment of the invention; For clarity, identical or similar elements are identified by identical reference signs throughout the figures. In the following description, the invention requires a convention of reading information. The invention is independent of this convention. [0025] A DOT positioned before another DOT in the horizontal direction is called, for example when a line is considered, a DOT which is upstream of another DOT in the conventional reading direction from left to right. [0026] Similarly, a DOT positioned before another DOT in the vertical direction is called, for example when a column is considered, a DOT which is upstream of another DOT in the conventional high reading direction. below. EMBODIMENTS [0027] FIG. 1 shows an example of an operating principle diagram of the main steps for generating a linear global two-dimensional code corresponding to a graphical representation of data. A parameter configuration step, denoted DEF. This step makes it possible to configure the parameters relating to: a table of correspondence of the data to be encoded; the dimensions of the overall linear two-dimensional code; and a volume of data to be encoded. A coding step, denoted C, makes it possible to encode data of an information flow. This data can be a set of characters or symbols. A calculator K makes it possible to implement the step of encoding the information. The coding includes the digitization of data or the processing of already digitized data. Each character, or tag, or symbol, is associated with a value V. This value V is the value of the character, or symbol, in a correspondence table. From this value V, the calculator calculates the polynomial, for example in base 2, representing the character. Take the example of the letter I and the Unicode correspondence table. The value of the letter I in the Unicode table is 73. The polynomial, in base 2, representing I is PI = 20 + 23 + 27. The coding step further allows encapsulation of data encoded by a data header and a foot of data. In addition to encapsulating the encoded data by a header and a foot, the data is binary ordered in a body, also called a heart, between the foot and the header. The step of generating a first set of symbols, denoted G, makes it possible to associate a symbology with the coding of the data. It is a step of generating a first set of graphic symbols S. This step includes the definition of a set of DOTs. A DOT is a physical form comprising a color, a shape and a size. This physical form can be square, rectangular, round, without restricting itself to these forms. In this embodiment, we are interested in the generation of square DOTs, having a solid color. Preferably, this color is white or black. An advantage of choosing these colors is to facilitate the discrimination of the DOTs during a reading of the code. These are arranged on at least one column and a certain number of lines so as to define a symbol 3. The symbol makes it possible to encode one or more data to be encoded. Each of the symbols of the first set of symbols is generated during step G. Each symbol comprises a header comprising at least one line, a core comprising a plurality of lines and a foot comprising at least one line. The number of lines of each symbol may be different depending on the nature of the data represented by the symbol. In Figure 1 is shown an example of symbol 3 comprising 3 DOT columns arranged on 11 lines including a header line, 2 foot lines and 8 core lines containing the data to be coded. The juxtaposition step J consists of juxtaposing the symbols of the first set of symbols generated during step G. Figure 1 represents a display area 1 and a code 2 comprising a plurality of symbols 3 juxtaposed. The code 2 can be read by an optical detector L, for example infrared. FIG. 2 represents the main steps of the coding of the information, the generation of the first set of symbols and the juxtaposition of these symbols: the coding comprises a step D of determining the type of information to be coded and of the identification of a possible policy associated with the information. By information is meant a set of ordered and typed data. This step also makes it possible to distribute the data according to one or more symbols according to predetermined criteria; a step, denoted by Nb C, of determining the number of columns of each symbol to be generated according to the data to be encoded as well as the definition of the associated DOTs. a step, denoted S, of generating the symbols according to the coding of the information. The symbol generating step comprises arranging the data DOTs and arranging them in the header and foot of each symbol; a last step, noted J, makes it possible to juxtapose the symbols of the first set of symbols. Such a juxtaposition has the advantage of eliminating size limitations. The capacity of the code is unlimited, and it is possible to juxtapose as many symbols as data to code. In addition, the size of the code is proportional to the volume of data to be encoded. The size of the DOTs is a function of the ratio of the volume of data to be encoded on the size of the code display area, these criteria being defined in step DEF. This size is expressed preferentially in pixels. The size of the DOTs is adjusted according to the area on which the code is to be placed. In one embodiment, the process configuration step may comprise the configuration of parameters relating to a translation value. If a translation value is configured, for each character, or tag, or symbol, the associated value V is the sum of: the value of the character, or symbol, in a lookup table; and the translation value. This translation value may be zero. When this value is not zero, it makes it possible to overcome the problems related to the value of the control characters such as BS (Backspace). Indeed, when printing these characters, a printer seeing the value corresponding to the control character BS will roll back, which is highly detrimental. In order to overcome this problem, the translation value can be 256, in order to shift the values of the data to be coded by 255. This translation value must be taken into account when decoding the generated code. FIG. 3 represents a linear global two-dimensional code generated by the method. In this example, the generated code comprises a first portion F1 comprising a plurality of DOTs (not fully visible in FIG. 3) ordered in rows and columns defining the data encoded by the step of encoding the information. In addition, it comprises a second part F2 defining the header of the matrix composed of a plurality of DOTs and a third part F3 comprising a plurality of DOTs ordered in rows and columns defining a foot of the code. The header comprises patterns formed of DOTs including the detection of a symbol or the orientation of the code by an optical reader. The header can have several forms: that of a continuous line (connected component) which is used to locate a line of symbols as well as its size and its limits in case of superposition of the lines of symbols. it can also be composed of a line composed of dots of parities complementary to those of the foot. The code comprises a third part F3 comprising a plurality of ordered DOTs in rows and columns defining a foot of the code. The foot of the code comprises patterns formed of DOTs for example to determine in particular the pitch of a DOT, that is to say, its size in pixels. Advantageously, this information enables an optical reader to detect the size of a DOT and to adapt the interpretation of the data to the reading step of the code to be analyzed. The foot consists of: - a last line consisting of either parity dots, usually odd, regular aliasing or a graphical scale to identify the columns - a penultimate line that encodes the last column of symbols; and - and 2 lines preceding the penultimate line that encode the type of symbols (characters, single or extended tags etc.). In the example of FIG. 3, the generated code comprises a plurality of juxtaposed symbols denoted S1, S2, S3, S4, S5, S6, S7. In this example, each symbol includes a number of identical lines and a number of columns specific to each symbol. Various techniques make it possible to discriminate between the 5 symbols, especially when their juxtaposition does not simply allow them to be differentiated: the graphic scale of the last line of the foot; a parity line; a vertical summation of the transitions detections 10 dot black / dot white and dot white / dot black on the different lines. Reading errors of a global linear two-dimensional code can occur for various reasons, in particular because: the size of the DOTs which can be reduced as much as possible so as to condense the coded information as much as possible; or else - a physical support degrading because of the flexibility allowing the support to bend and become damaged; or else - a superimposed impression such as a signature that may interfere with the interpretation of the data; that the gray levels of the DOTs can be difficult to discriminate, in particular with the wear caused by the degradation of the support over time or a defective illumination. In order to avoid reading errors and to optimize the decoding of data, it is possible, in embodiments, to generate sets of redundancy symbols. In this case, it is possible to define data relating to a redundancy calculation during the process configuration step. These data are: the type of redundancy calculation to be performed: for example Hamming or Reed Solomon; and associating or using them separately; the percentage of redundancy data relative to the data to be coded. When a Reed Solomon redundancy calculation is chosen, the size of the image varies linearly to a threshold where it is jumped, then linearly thereafter to a next threshold. This threshold varies according to the chosen configuration of Reed Solomon, that is to say according to the percentage of redundancy data with respect to the data to be coded. For example for a "44 + 15" configuration, ie a configuration such that there are 15 redundancy symbols for 44 data symbols to be coded, the length 1 of the code, for n data symbols to Total coding will be: 0 to 44, 1 = n + 15; +15; for n ranging from n for n ranging from 45 to 89, 1 = n + + 15 + 15; 90 to 134, 1 = n and so on.

Other Reed Solomon calculation configurations exist, for example "115 + 40". Once the data relating to a redundancy calculation have been defined, the method codes said data in binary form. In one embodiment, the method may comprise a step of generating a second set of symbols called redundancy symbols. These symbols have the characteristic of encoding redundancy information of a DOT line of a plurality of symbols of the first set of symbols. They may advantageously include information making it possible to know the number of symbols of the first set of symbols of which they code the redundancy. Each symbol of the second symbol set comprises: at least one column of DOTs, each DOT comprising a color, a shape and a size depending on the ratio of the volume of data to be encoded to the size of the code display area; at least one line forming a header; A plurality of lines comprising the binary data relating to a redundancy calculation; at least one line forming a foot; After the generation of the second set of symbols, the method comprises a juxtaposition step of this second set of symbols following the first set of symbols juxtaposed. Such a step has the advantage of ensuring that all information will not be lost when parts of the 2D code are unreadable. Indeed, even if the unreadable parts of the code exceed the programmed redundancy rate, it will be possible to read the unaffected parts of the code. In another embodiment, the method may comprise a step of generating a third set of 5 symbols called redundancy symbols. These symbols have the characteristic of coding a redundancy information of a line of DOTs of a plurality of symbols of the first set of symbols. They may advantageously include information making it possible to know the number of symbols of the first set of symbols whose redundancy they encode. Each symbol of the third symbol set comprises: at least one column of DOTs, each DOT comprising a color, a shape and a size depending on the ratio of the volume of data to be encoded to the size of the code display area; at least one line forming a header; a plurality of lines including the binary data relating to a redundancy calculation; at least one line forming a foot; After the generation of the third set of symbols, the method includes a step of inserting symbols of the third set of symbols between symbols of the first set of juxtaposed symbols. Such a step has the advantage of ensuring that all information will not be lost when parts of the 2D code are unreadable. Indeed, even if the unreadable parts of the code exceed the programmed redundancy rate, it will be possible to read the unaffected parts of the code. In embodiments, after the steps of: juxtaposing the symbols of the first set of symbols; or juxtaposing the symbols of the second set of symbols following the symbols of the first set of symbols; or inserting symbols of the third set of symbols between the symbols of the first set of juxtaposed symbols, in combination, optionally, with the step of juxtaposing the symbols of the second set of symbols following the symbols of the first set of symbols; the code can be printed on at least one line. Figure 4 illustrates an impression of an example code generated on several lines. Line 21 is a line on which part of the code is printed. This printing step comprises a step of calculating the number of lines on which the code will be printed. The number of rows is calculated based on the size of the DOTs, the volume of coded data, and the dimensions of the code. This printing of the code, which is the impression of the juxtaposition of the symbols is carried out so as to define a general form of the code for an orientation and a direction of reading suitable for the realization of a step of decryption of the data by an optical reader. Indeed, the first and the last line of the code, or each part of the code when it is printed on several lines as illustrated in Figure 4, include information about the connected component and the parity dots. This defines a direction of code orientation. According to the embodiments of the code may be printed on any type of support paper, plastic, or any other printable medium. In the context of the printing of the code on a support 5 20, as illustrated in FIG. 4, the dimensions of the code correspond to the surface of the display area available on the medium on which the code is printed. Thus, in the case of the authentication of an invoice, for example, an area will be reserved on the invoice for printing the code, which may serve to authenticate the invoice. The dimensions of this area correspond to the dimensions of the code. The invention also relates to a global linear two-dimensional code. This overall two-dimensional linear code is the juxtaposition of a set of symbols representing data to be encoded. Each symbol of this set of symbols comprises at least one column of DOTS whose size is a function of the ratio of the volume of data to be encoded and the dimensions of the global linear two-dimensional code, for example when it is printed on a physical medium. These dimensions of the overall two-dimensional linear code are the expected dimensions, that is to say the dimensions of the area on which said code will be printed or represented. Finally, the invention relates to a computer program, executable by means of processing a computing device, for the execution of a method for generating a global two-dimensional code. This program groups in a single process all the operations performed sequentially by a font generator on the one hand, and then on the other hand by a text editor that implements these fonts. Thus, this program will successively create each symbol according to a given structure and then assemble the symbols according to the imposed compositional criteria. For a given symbol structure, there is a generator software unless you set the choice of structures in the generator. In the other case the symbol structure change is made by changing the font in the font generator. The invention has been illustrated and described in detail in the drawings and the foregoing description. This must be considered as illustrative and given by way of example and not as limiting the invention to this description alone. Many alternative embodiments are possible. In the claims, the word "comprising" does not exclude other elements and the indefinite article "a" does not exclude a plurality.

Claims (13)

REVENDICATIONS1. A method of generating a linear global two-dimensional code comprising the steps of: configuring parameters relating to a data map to be encoded, to the dimensions of the global linear 2D code, to the data volume to be encoded; encoding data in binary form from values defined in the correspondence table and said translation value; generating a first set of symbols in which each symbol comprises: at least one column of DOTs, each DOT comprising a color, a shape and a size; at least one line forming a header; a plurality of lines comprising the coded bit data; and at least one line forming a foot; juxtaposition of the symbols of the first set of symbols. 2. Method according to claim 1 characterized in that the configuration step comprises the configuration of parameters relating to a translation value. 3. Method according to any one of the preceding claims, characterized in that the size of the DOTs is a function of the ratio of the volume of data to be encoded on the dimensions of the global linear two-dimensional code. 4. Method according to claim 1 characterized in that the configuration step comprises the definition of data relating to a redundancy calculation. 5. Method according to claim 4 characterized in that it comprises a step of encoding the data relating to a calculation of redundancy in binary form. 6. Method according to claims 3 and 5 characterized in that it comprises: a step of generating a second set of symbols called redundancy symbols, each symbol of said set comprising: at least one column of DOTs, each DOT comprising a color, shape and size; at least one line forming a header; a plurality of lines including the binary data relating to a redundancy calculation; at least one line forming a foot; a juxtaposition step of the second set of symbols following the first set of juxtaposed symbols. 7. Method according to claims 3 and 5 characterized in that it comprises: a step of generating a third set of symbols called redundancy symbols, each symbol of said set comprising: at least one column of DOTs of predefined size, each DOT comprising color, shape and size - at least one line forming a header; a plurality of lines comprising the binary data relating to a redundancy calculation; at least one line forming a foot; a step of inserting symbols of the third set between symbols of the first set of juxtaposed symbols. 8. Method according to any one of the preceding claims characterized in that it comprises an additional step of printing the code, printing on at least one line. 9. The method of claim 8 characterized in that the printing step comprises a step of calculating the number of lines according to the size of the DOTs, the volume of coded data and the dimensions of the overall linear two-dimensional code. 10. Method according to any one of the preceding claims, characterized in that the juxtaposition of the symbols of at least one of the sets of symbols is performed so as to define a general form of said code for an orientation and a reading direction suitable for performing a step of decrypting the data by an optical reader. 11. Method according to any one of the preceding claims, characterized in that said dimensions of the overall linear two-dimensional code correspond to the surface of a display area of a medium on which said code is capable of being printed. A global linear two-dimensional code composed of a juxtaposition of a set of symbols, each symbol comprising at least one column of DOTs, characterized in that the size of said DOTs is a function of the ratio of the volume of data to be encoded and the dimensions of the data. overall two-dimensional linear code. 13. Computer program comprising instructions for executing the steps of the method of generating a linear global two-dimensional code according to one of claims 1 to 11 when said program is executed by processing means of a computing device .15