FR3058605B1 - METHODS OF MAKING AND / OR RETRIEVING MULTIPLE-CLIQUABLE EMAIL SIGNATURES, E-MAIL MANAGEMENT SYSTEM THEREFOR - Google Patents

Abstract

The invention relates to an email management system (M) comprising a signature (SG) designating an image (I) comprising one or more clickable zones (ZI1, ZI2). To make such a signature searchable by any electronic mail client (MUA), a signature server (LSI) is arranged to implement a method (200) for producing fragments (FI) of said image (I), in response upon receipt of fragment (RF) requests transmitted by such a mail client when interpreting a set of program instructions (SCP) describing said signature (SG) as an association of adjacent containers provided to host said image fragments (FI), or, for some, a hyperlink. The invention further relates to a method of assisting the development (100) of such an interoperable signature (SG).

Description

The invention relates to the management of email bodies, also called electronic messages or "mails" according to an English terminology, and more particularly signatures included in said bodies of such emails, especially if they include graphic contents comprising one or more clickable areas. In the rest of the document, "clickable zone" will be understood to mean an area of a first document associated with a link to a second document. These links are commonly referred to as "hyperlinks" and are particularly used in the Internet world. They thus make it possible to trigger the display, by means of an Internet browser or any other software allowing such visualization, of said second document in response to a mouse click, or any other pointing device, on a textual element or graph present in said area of the first document.

E-mail is today one of the main media used to exchange information between two or more people. This method of communication relies on a service for the electronic transmission of a written message, and of one or more documents possibly attached to said written message, via a computer network, mainly the Internet, intended for one or more mailboxes. one or more recipients designated by the issuer of the said written message.

To send and / or receive an e-mail, it is indeed necessary to have an e-mail address and a mail client (or alternatively an electronic portal allowing access to said e-mail via an Internet browser).

In order to ensure good interoperability (that is, so that an e-mail can be elaborated, transmitted, then received and consulted by a plurality of computer tools), the routing or routing and the content of the e-mails are regulated. by standards. However, a recipient may not receive a true copy of the email developed and viewed on its screen by the sender of said message.

Indeed, at the origin of the service of electronic transmission of a written message, an e-mail was a document which only contained text in standardized format ASCII (American Standard Code for Information Interchange according to an English terminology). It therefore contained only characters necessary to write in English. Such a message, devoid of accentuated or regional characters, did not raise any risk of being perceived differently on a post of a recipient. Nowadays, many characters are available, including regional characters, and it is even possible to attach one or more files or documents to an email. This enrichment of e-mails has been possible thanks to the advent of the MIME standard (Multipurpose Internet Mail Extensions according to an English terminology or Multifunction Extensions of Internet Mail in a French terminology). The use of HTML (HyperText Markup language according to English terminology) also allows you to structure and format e-mail. Such language literally translates into "hypertext markup language". Using predefined markers, which we will call "tags", it is possible to structure a document and especially to insert one or more hyperlinks that, when clicked, trigger the consultation of a second document or resource . For example <a> is the opening tag of an element of a document, and </a> the closing tag of that element. If said element has the tag HREF = target.html, where "target.html" is an attribute specifying the name of a document whose view is to be triggered after a click, the element has a clickable area. We will detail later some main tags.

The HTML language offers a good level of interoperability, however some emails written using this language still present a significant risk of loss of compliance, because some tags are not recognized by some e-mail software or even interpreted in a way disparate. Such a risk of loss of compliance was also highlighted in 2007 by the W3C or World Wide Web Consortium's W3C HTML Mail Seminar, using an English terminology from which W3C, a non-profit, standardization organization to promote the compatibility of the technologies exploited in the Internet world.

To circumvent this difficulty, it is customary to respect certain implicit rules when developing the body of an email. Likewise, knowledge of certain technical aspects makes it possible to avoid misunderstanding or communication. We will distinguish in the following of the document, the body of an email of the header of this one. A header contains the contextual information of the email: identifier of the sender, identifier of the recipient, a string characterizing a title or the subject of the email, a date of sending the email, or even attributes, such as the character emergency, etc. The body of the email is, in turn, encoded as one or more blocks of text, images, links. Most email bodies have a signature. This is generally common to a plurality of emails developed by the same issuer, and contains text or even images.

To avoid the losses of conformity some emitters will privilege bodies of simple emails in their structure and contents. However, messages sent in the form of emails give their recipients an image of the sender. Too much sobriety of an e-mail can lead to an incorrect perception of the sender by a recipient.

In addition, the signature of a message offers the issuer the opportunity to convey information complementary to the message as such, for example on its activity or on an event which said issuer wishes to attract attention, so incidental, of the recipient. It is therefore sometimes prohibitive or unfortunate to do without this opportunity for reasons of maintaining compliance.

Many actors try to propose solutions to develop and add to an email a signature elaborate and sometimes selectable among a plurality.

However, these solutions encounter, to date, problems of loss of compliance of messages by the use of tags sometimes unrecognized by hundreds of applications or e-mail clients, or of limiting the richness of the content of said signature. In particular, when the sender wishes to integrate into the body of his email a signature comprising one or more clickable images, he has no choice but to associate the entirety of said image with a single hyperlink. The issuer is therefore forced to use various signatures if he wishes to draw the reader's attention to different events or news. The invention thus makes it possible to solve the aforementioned limitations by proposing, on the one hand, a process for generating signatures or, more generally, email bodies comprising one or more clickable images each associated with a plurality of hyperlinks and links. on the other hand, to ensure a flawless compliance of these e-mails by favoring the exploitation of main tags recognized by all e-mail clients. To this end, it is intended, first of all, a method of delivering a fragment of a designated image in a signature of an email. Such a method is intended to be implemented by a processing unit of a signature server further comprising communication means for receiving a request for content sent by a third electronic device and for transmitting, in response to a request. such content request, content in the form of a content message, said signature server cooperating with a data memory comprising a container associated with said signature. To provide excellent interoperability to an email exploiting such a signature, first of all, said container comprises a digital representation of the image in a matrix form of pixels whose respective integer values describe light intensities. In addition, such a method for delivering a fragment of an image comprises: a step for identifying a request for content, received by the communication means of the signature server, as a fragment request and for extracting from it data conveyed by said fragment request; a step for decoding said data extracted from the fragment request and determining: i. the value of the identifier of the container of the digital representation of the image; ii. geometric data determining a fragment of said image by delimiting a subset of said representation of the image; a step for reading, in data memory, the digital representation of the image whose container identifier value has been extracted; a step for producing a new digital representation, based on the digital representation of the image and the geometric data previously extracted, describing a fragment of the image; a step for encoding said new digital representation describing a fragment of the image in the form of a content message; a step for triggering the transmission of said content message to the third electronic device by the communication means of the signature server.

To discriminate a fragment request from among all other content requests, when these convey data consisting of a character string, the step to identify such a request as a fragment request may consist in recognizing in said string of characters the presence of a predetermined keyword.

According to a first embodiment, it can be provided that: the geometric data extracted from a fragment request can consist of a set of integers respectively designating characteristic points of a polyline; the step of producing the new digital representation describing the required image fragment can then consist in creating a digital representation in a matrix form of pixels whose integer and respective values are identical to those of the only pixels of the digital representation of the image. image captured by said polyline.

In a variant, the invention provides that: the geometric data may consist of a quadruplet of integers describing: first and second vertical rows in number of pixels, from a reference pixel within the digital representation of the image , the value of the second vertical row being greater than that of the first; first and second horizontal ranks in number of pixels, from said reference pixel within said digital representation of the image, the value of the second horizontal row being greater than that of the first; the step of producing the new digital representation (RFI) describing the required image fragment (FI) can then consist in creating a digital representation in a matrix form of pixels whose integer and respective values are identical to those of the only pixels of the digital representation of the image of which: the horizontal rows are between said first and second horizontal rows; the vertical rows are between said first and second vertical rows.

In order to be able to adapt the operation of a signature server, the invention furthermore provides a first computer program product comprising a plurality of program instructions which, when they are previously loaded into the program memory of such a program product. a signature server, said server further comprising a processing unit, communication means for interacting with a third electronic device, a data memory, and then executed or interpreted by said processing unit of said signature server (LSI), causes the implementation of a method of delivering a fragment of an image according to the invention.

In the same way, the invention relates to such a signature server comprising a processing unit, communication means for interacting with a third electronic device, a data memory and a program memory recording the instructions of a first product computer program, as expressed above.

According to a second object, to simplify the development of a signature of an interoperable e-mail, the invention also relates to a method for producing a signature of an e-mail, said signature designating an image, said method being set implemented by a processing unit of an electronic device further comprising a data memory recording a digital representation of the image in a matrix form of pixels whose respective integer values describe light intensities, an input interface. Such a method, comprising a processing for producing a representation describing said signature, a step for encoding said structure in the form of a message requesting the registration of said signature with a remote signature server, is arranged to include: a a step of collecting N input data sets from the input interface, N being a non-zero integer, for which an input data set comprises: i. geometric data of a polyline delimiting a clickable area; ii. a character string translating a hyperlink associated with said area of the image; a step for determining a fragmentation grid from said geometric data of said N sets of input data.

Such a method is arranged, according to the invention, so that the processing for producing a representation describing said signature consists of the elaboration of a set of program instructions, said program instructions being chosen to: be automatically interpreted by an electronic mail client, implemented by a third-party electronic device, triggering a graphic rendering of an email comprising the signature and, jointly translating an association of adjacent containers of fragments, respectively associated with fragment requests, said requests being interpretable by a signature server according to the invention, as described above, and each conveying data including: - the value of a container identifier of the digital representation of the image; geometric data determining a fragment of said image by delimiting a subset of said representation of the image, said geometrical data being determined from the fragmentation grid.

According to a preferred embodiment, the invention provides that: the geometric data derived from the input data can describe a rectangular polyline; the step of determining a fragmentation grid from said geometrical data of said N sets of input data which can then consist of determining [2N + 1] horizontal tabulations and [2N + 1] vertical tabulations with respect to a pixel of reference of the representation of the image; processing to develop a representation describing said signature as a set of program instructions that may consist of producing one or more program instructions for: i. describe a table of [2N + 1] 2 containers of image fragments, divided into [2N + 1] rows and [2N + 1] columns; ii. the geometric data conveyed by each fragment request delimiting the image fragment being determined according to the horizontal and vertical tabulations previously determined respectively. As a particularly advantageous embodiment and promoting the deployment of the invention, the set of program instructions produced to describe the signature can be in accordance with the programming language "HyperText Markup Language" in English terminology.

To provoke the implementation of such a process for producing an interoperable signature, by a large majority of existing electronic devices, the invention provides for adapting the operation of such devices by a second computer program product including a plurality of program instructions which, when it is: - previously loaded into the program memory of an electronic device, said electronic device further comprising a processing unit, communication means for interacting with a server of signatures, a data memory and an input interface, - then executed or interpreted by said processing unit of said electronic device, causes the implementation of a method of generating a signature of an email according to 1 'invention.

Thus, the invention also relates to an electronic device comprising a processing unit, communication means making it possible to interact with a remote signature server, a data memory, an input interface and a program memory recording the instruction instructions. such a second computer program product according to the invention.

Finally, the invention relates to any email management system, since it comprises a signature server according to the invention, and said server cooperates with an electronic mail client of an electronic device by means of a or multiple requests in fragment of an image designated in a signature of an email displayed by said email client.

Advantageously, but optionally, such a system may further comprise a second electronic device cooperating with said signature server by means of a message requesting the registration of said signature with the signature server, said second electronic device being adapted by installation, in a program memory, of a second computer program product as evoked above and in accordance with the invention. Other features and advantages will appear more clearly on reading the description which follows and on examining the figures which accompany it, among which: FIG. 1 describes an exemplary architecture of a compliant e-mail management system to the invention; FIG. 2 describes an example of a method for producing and / or making available an email signature according to the invention; FIGS. 2A and 2B respectively illustrate two examples of a signature comprising a clickable image encoded according to a method for producing and / or making available an email signature according to the invention; FIG. 3 describes a method for delivering a fragment of an image of a signature implemented by an email signature server adapted according to the invention.

FIG. 1 shows an exemplary architecture of an email management system M according to the invention. As mentioned previously, an email M consists mainly of a header E and a body MC. The latter may include text or other figurative or semi-figurative elements. Said body MC generally has an SG signature.

Whether U1 issuer or potential recipient U2 or U3 of an email, each user operates a MUA electronic mail software implemented by an electronic device, such as a personal computer Dl, a smartphone D2 or a tablet D3 . Such software or MUA email client is generally named a User's Email Agent, or Mail User Agent according to English terminology. Most such MUA clients are active, or implemented, only when the user wishes to develop an email M then issue it or when said user wishes to view emails M that were sent to him. Emails M elaborated and issued by the user U1 are registered and hosted by a server or MTA e-mail transfer agent, generally referred to as the English language version of the Mail Transfer Agent.

The latter cooperates via a network, generally the Internet, with an e-mail delivery agent MDA, generally known by the common name Mail Delivery Agent, associated with the recipient U2 or U3, which stores the e-mails addressed to said recipient U2 or U3, such as a mailbox or mailbox according to English terminology.

Said e-mail delivery agent MDA cooperates with the software or email client MUA of said recipient U2 or U3, so that the emails can be downloaded, manually or automatically, and then viewed by said user U2 or U3 on the screen of his device D2 or D3 electronics.

There are already service providers for centralizing a bank of signatures SG available for a user who subscribed to this service, in this case the user U1 in Figure 1. For this, an LSI signature server memorizes one or more signatures SG, that is to say that said server LSI allocates a composite record in one of MD data memories with which it cooperates, said record generally comprising a text and / or an image possibly clickable. During the installation of the U1 user's MUA mail client or on manually or automatically triggered requests, said MUA client proposes that said user U1 select an SG signature from a plurality available using an appropriate graphical interface. The user U1 can thus integrate in the body MC of an email M the content of the signature SG selected. Said MUA client thus cooperates with the LSI server by means of RS requests to request the downloading of SG signature contents from the LSI server, said contents being transmitted to the MUA client by SS messages arranged for this purpose.

Such an email management system is adapted according to the invention in that the LSI signature server can implement an innovative method for producing on the fly image fragments, hereinafter referred to as "fragment (s)". for the sake of simplification, and sending such fragments, in response to an RF fragment request issued from a conventional MUA messaging client. Said FI fragments of the same image I, some of which are clickable because associated with possibly different hyperlinks from each other, are developed and then addressed by SF messages, by the LSI server to the MUA mail client requesting said fragments. Said requesting client may be that of a publisher and future emitter of an email integrating the signature designating image I or that of a recipient of such an email. The RF and SF messages result from a clever exploitation of a tabular representation of images contained in an SG signature. Such a representation can be translated by a set of program instructions or SCP script, for example a succession of tags if, preferably but not limited to, such an SCP script exploits the HTML language. Unlike the state of the art, an image I integrated in the body MC of an email M is not conveyed as such by the body of said email, or even attached to it as an additional piece . The invention provides that said image I is reconstructed on the fly, such as a dynamic puzzle, during the editing or visualization of said body MC e-mail M. The invention further provides to adapt or provide software MAA SG signature editing system comprising a clickable image, operated by the U1 user or by a user U4 responsible for designing such signatures SG. Such a MAA tool is arranged to be implemented by an electronic device D1 or D4, such as a computer or any other electronic object capable of implementing said software. The latter cooperates with the LSI signature server by means of STS requests making it possible to load, from the device Dl or D4 implementing the MAA agent, into the memory of the LSI signature server, the CMS body of a SG signature designed by U1 or U4 user. Said SGC body may be associated with a header or more generally with one or more EGC attributes governing access to said SG signature, like those currently managed according to the prior art. The cooperation between the MAA agent and the LSI server further allows the U1 or U4 user to collect, by RDS messages, the content of an SG signature already registered in the LSI server for editing or updating. said SG signature prior to a new registration thereof in said LSI server.

FIG. 2 describes respectively a method 100 for generating a signature SG comprising an image I whose ZIN area is clickable and possibly loading said signature SG in a memory of an LSI signature server. Such a method 100 is intended to be implemented by a processing unit of an electronic device operated by a signature creator SG, for example the user U4 described in connection with FIG.

FIG. 3 will describe later a method 200 for generating and transmitting an IF fragment of such an image I destined for a MUA messaging client of a user sending or receiving an email M whose body MC includes said SG signature. Such a method 200 is meanwhile intended to be implemented by a processing unit of an LSI signature server.

The term "processing unit" in the rest of the document, any processor, microprocessor and / or microcontroller capable (s) to cooperate with one or more memories and adapted (s) to automatically implement a method 100 or 200, for example, by the interpretation or execution of instructions of a computer program P100 or P200 previously loaded within one of said memories. Generally, such program instructions are recorded in an integrated program memory or cooperating with said processing unit, memory is represented, nor referenced in FIG.

FIG. 2 thus describes a method 100 for generating an email signature M of an email M comprising an image I comprising a clickable zone ZIn. A first example of an image I and the development of an SCP script, expressed in HTML language, describing or representing said image I is illustrated by FIGS. 2A and 2B.

According to FIG. 2A, the image I comprises only a zone or region ZI1 that can be clicked whereas according to FIG. 2B, said image I comprises two zones ZI1 and ZI2 that can be clicked respectively associated with distinct hyperlinks. The exemplary implementation of a method 100 described with reference to FIGS. 2, 2A and 2B is based on the HTML language. In order to offer excellent interoperability, an SCP script, that is to say a succession of instructions or tags expressed in said HTML language, generated by said method 100 and describing a clickable image I is mainly based on the <table> and <img> tags interpreted consistently and identically by currently available MUA email clients.

Recall briefly the syntax related to these two tags.

The <table> tag is a very popular container in web pages. It facilitates the formatting of information in the form of a table or a table, by cutting into lines and cells of parametric sizes. The <table> tag itself relies on the <tr> and <td> tags for formatting elements within the table. For example, the <tr> tag creates a new line, and the <td> tag creates a cell within a row. The <table> tag can have one or more attributes to determine display properties of the table. Among the main ones, the "cellspacing" attribute specifies a spacing in number of pixels between two adjacent cells within the same line. The attribute "cellpadding" specifies a space in number of pixels between the edge of a cell and its contents. Other attributes such as "style" or "border-collapse" determine the possible display of borders materializing the cells, said borders being also invisible if necessary.

The <img> tag links an image to a document by specifying a source through the "src" attribute. It is by using, in a clever way, the content of this "src" attribute, that the invention makes it possible not to resort to tags raising interoperability problems, such as the <map> tag sometimes exploited to determine a clickable zone d. 'a picture. An SG signature developed in accordance with the invention thus remains compliant, after having been integrated in the body MC of an email M, during the consultation of said email M by a recipient. Let's describe Figure 2A. This illustrates an image I whose digital representation RI in the form of a matrix of pixels comprises several semi-figurative items (that is to say comprising an illustration and / or a text). By abuse of language, let us mention that the image I extends over a height HM of three hundred pixels and on a width LM of five hundred pixels. Such an image I is similar to five items separated graphically by horizontal and vertical lines. Each section contains a text, "Text 1", ... "Text 5". Some sections also include a drawing. For example, the section containing the text "Text 2" further comprises an area circling said text. In the same way the text "Text 5" is written in a frame.

FIG. 2A also illustrates, by means of hatching, a zone ZI1 created by the designer of the signature SG, by means of a suitable input interface, advantageously graphic, associated with a pointing device, the perimeter of which is materialized by a polyline of rectangular shape, the geometrical data of which are known, expressed for example in the form of a series of numbers of pixels or ranks, expressed from a reference point of the image I, in this case the upper left corner of said image I, ie the pixel of coordinates (rh = 0, rv = 0) where rh signifies a horizontal row in number of pixels and rv signifies a vertical row in number of pixels. According to the example described with reference to FIG. 2A, a zone ZI1 has been created whose upper left corner is the coordinate pixel (42,33) whose width is one hundred and ninety-six pixels and whose height is seventy-two pixels.

Said designer wishes to make the interior of said polyline clickable. Thus, by means of a suitable input interface, for example a keyboard, it provides the content of a hyperlink HREF1, in this case "www.page.html" according to the example described in Figure 2A.

A method 100 according to the invention, described by way of non-limiting example in FIG. 2, may comprise a step 101 for selecting or developing an image I intended to be designated or used in the body of an email. such method 100 includes a step 102, possibly iterative, to determine one or more zones ZIn on the image I and associate with said delimited zones ZIn a hyperlink HREFn determined to make said zones ZIn clickable.

According to the example described with reference to FIG. 2A, zone ZI1 was created in step 102. The processing unit implementing said method thus knows the geometrical data of said zone ZI1. By way of nonlimiting example, said geometric data of a zone ZIn may consist of a quadruplet of integers ZUn, ZDn, ZLn and ZRn, respectively describing, in number of pixels from the upper left corner of the image I: - ZUn: the vertical rank of the pixel describing the upper left corner of the ZIn zone; - ZDn: the vertical rank of the pixel describing the lower left or right corner of the ZIn zone; - ZLn: the horizontal rank of the pixel describing the top or bottom left corner of the ZIn area; - ZRn: the horizontal rank of the pixel describing the top or bottom right corner of the ZIn area.

According to the example illustrated in FIG. 2A, the zone ZI1 is therefore characterized by the quadruplet of integers: ZUn = 42; - ZDn = 114; - ZLn = 33; - ZRn = 229.

The method 100 described in connection with FIG. 2 now includes a step 103 for defining horizontal and vertical tabs in order to size the future IF fragments of the image I.

When an image I has N clickable zones ZIn (where 1 <n <N) of substantially rectangular shapes, [2N + 2] horizontal tabulations THO to TH2N + 1 and vertical tabulations TVO to TV2N + 1 are determined in step 103 Thus, the number of fragments FI to be sized is equal to [2N + 1] 2, that is, in the present case nine (because N = 1) for the example illustrated in FIG. 2A or twenty-five (because N = 2 ) for the example according to Figure 2B which will be described later where two zones ZI1 and ZI2 are clickable.

The horizontal tabulations THi (where i is an integer such that 0 <i <2N + 1) result from a storage operation in ascending order of the elements ZL1 to ZLN and ZR1 to ZRN, resulting from the N quadruplets describing the N clickable zones, to which are added the left limit values Lm and LM of the image I considered, that is, in this case in the image I illustrated in connection with Figure 2A, Lm = 0 and LM = 500.

The vertical tabs TVj (where j is an integer such that 0 <j <2N + 1) result from a storage operation in ascending order of the elements ZU1 to ZUN and ZD1 to ZDN, resulting from the N quadruplets describing the N clickable zones, to which we add the high limit values Hm and low HM of the image I considered, that is, in this case in the image I illustrated in connection with Figure 2A, Hm = 0 and HM = 300.

The different horizontal and vertical tabulations thus elaborated constitute the equivalent of a fragmentation grid, from which fragments of image will be sized.

Method 100 now includes a process 110 for constructing a set of program instructions or tags intelligible by any MUA mail client. Such a processing 110 may comprise, by way of example, a step 111 for initializing a table or table structure whose object consists in describing the image I, whose clickable zone ZI1, such as a puzzle of nine fragments FI of image, as described by the discontinuous lines, in Figure 2A, from the horizontal and vertical tabulations previously developed and constituting a fragmentation grid. According to an example of a preferred but nonlimiting application of a method 100 based on HTML, an SCP script developed by the processing 110, includes a first <table> type tag such as: <table cellspacing = "O "cellpadding =" O "style =" border-spacing: 0; border-collapse: collapse; ">

According to this example, the attributes "cellspacing" and "cellpadding" specify that no space is to be expected between the image fragments that will be expressed later in the form of cells of a table. Similarly, the values of the "border style" and "border-collapse" attributes specify that no border delimiting said cells should be visible. Step 111 further consists in initializing the index j, associated with the vertical tabs TVj, so that said index j takes the value 0.

According to the example described in FIG. 2A, the image I comprises a number N = 1 of clickable zones. The implementation of a method 100 will now make it possible to describe the image I in the form of a fragmented structure of said image I, more precisely to constitute an association of containers, for example in the form of a table of 2N + 1 = 3 lines, each with 2N + 1 = 3 cells or adjacent containers. Each cell comprises one or more program instructions expressing a fragment request, interpretable by an LSI signature server according to the invention, conveying data among which: the value of an identifier of a container RSG associated with the signature designating the image I, said RGS container being registered within a data memory MD of the LSI signature server; geometric data delimiting an IF fragment of said image I by delimiting a subset of the image (I), said geometric data being determined from the fragmentation grid.

The processing 110 of the method 100 then comprises a step 112 for, on the one hand, initializing the index i associated with horizontal tabulations THi, the latter taking a zero value and, on the other hand, to add a creation instruction of a line in the table initiated in step 111. This line will correspond to an area of the image I located above the upper limit of the zone ZI1 determined by the value of the integer ZU1. The SCP script thus has a <tr> tag to create said line.

The method 100 therefore comprises a series of steps 113, 120, 114, 115, said series being implemented iteratively as long as the value of the index i remains below the value 2N + 1 (situation represented by the step 115 in FIG. 2 and by the link 115-y), ie the value 3 as regards the example described in FIG. 2A where N = 1. Step 113 consists in calculating geometrical data, which parameterizes a subsequent step 120 intended to allocate in the jth current row of the array, an ith cell associated with an image fragment FIi, j, which will be elaborated and transmitted by the LSI signature server in response to the interpretation of an RF fragment request whose fragment geometric data conveyed by it are defined in step 113. Thus, said cell is determined to be the future container of said FIi fragment j. Thus, at each iteration of step 113, said geometrical data delimiting the i th fragment FI 1, resulting from an RF fragment request specified in the i th cell of the current j th line, can be defined in the form of a quadruplet integers, Ui, j, Di, j, Li, j and Ri, j, for which: - Ui, j: denotes the vertical rank of the pixel describing the upper left corner of the fragment Fii, j; - Di, j: the vertical rank of the pixel describing the lower left or right corner of the fragment FIi, j; - Li, j: the horizontal rank of the pixel describing the top (or bottom) corner to the left of the fragment FIi, j; Ri, j: the horizontal rank of the pixel describing the right up (or down) corner of the fragment FIi, j.

The values of the members of said quadruplet are initialized in step 113, starting from the values of certain horizontal tabulations THi or vertical TVj determined previously, as follows: - Ui, j = TVj; - Di, j = TVj + 1; Li, j = THi; - Ri, j = THi + 1.

According to the example illustrated in FIG. 2A, the first fragment FI0.0 is determined by the quadruplet of integers (U0.0 = 0, OD, 0 = 42, LO, 0 = 0, RO, 0 = 33). The step 120 of creating a cell or container in the current line advantageously consists of three substeps 121, 122 and 123. The step 121 may consist mainly of producing in the SCP script, according to the example described in connection with FIG. 2A advantageously relies on the HTML language, a tag <td> followed by a tag <img> having as its argument src a string of characters comprising concatenated fields via a determined separator, in this case the separator '/ '. Said string produced in step 121 specifies or encodes a "fragment" keyword, characteristic of an image fragment management, keyword that will be exploited by the method 200 described later, a file name or more generally an identifier of a container of a digital representation RI of the image I recorded by the signature server LSI (identifier corresponding to "img.jpg" in the example of FIG. 2A) and the parameters of future elaboration by the signature server LSI of a fragment FI of said image I. Said string of characters, argument of the tag "src" can constitute a URL, Uniform Resource Locator according to an English terminology, transportable by the HTTP protocol, HyperText Transfer Protocol according to an Anglo-Saxon terminology or literally "hypertext transfer protocol", a client-server communication protocol developed for the Internet world. Such a URL conveyed by the HTTP protocol will constitute an RF fragment request sent from a conventional MUA messaging client when said client triggers the display of the body MC of an email M containing a signature SG designating the image I.

According to the example of FIG. 2A, the parameters (or geometrical data) of future elaboration by the LSI signature server of a fragment of said image I mentioned above correspond to fields of respective values Ui, j, Di, j , Li, j and Ri, calculated in step 113. These values are advantageously encoded and concatenated downstream of a separator, for example "? ".

Indeed, the syntax of a string defining a request transmittable by the HTTP protocol (or query string according to English terminology), expressed in HTML, comprises a plurality of fields separated by the symbol. Each of said fields consists of a field-value pair corresponding to a field name and a content of said field, separated by the symbol '='. For example, such a string can be written in the form: fieldl = valuel & field2 = value2 & field3 = value3 where the fields fieldl, field2 and field3 are respectively valuel, value2 and value3.

Thus, the geometrical data "upper" takes the value of Ui, j, the geometrical datum "lower" takes the value of Di, j, the geometrical datum "right" takes the value of Ri, j and the geometrical datum "left" takes the value of Li, j. Said geometric data can be concatenated and separated using a separator such as' &amp; for example.

Thus, the <img> tag associated with the first cell of the array can take the scr = "/ fragment / img.jpg? Upper = 0 & lower = 42 &amp; right = 33 & left = 0" argument.

Assuming that the fragment FIi, j thus dimensioned is covered by a clickable zone ZIn, the SCP script includes a program instruction specifying the hyperlink concerned. For this, the step 120 comprises a substep 122 of the coverage test of the current fragment by a clickable zone ZIn defined in step 102. It suffices for that to compare the geometric data of this fragment with those of the clickable zones. Zin. In the affirmative (situation symbolized by the link 122-y in FIG. 2), the step 120 includes a substep 123 to add in the SCP script a <a> tag with the "href" argument as the address or URL designating the web page that you want to reach. In connection with the fragment FI0,0, of Figure 2A, it is not (situation symbolized by the link 122-n in Figure 2). Step 120 ends with the addition in the SCP script of the cell closing tag </ td>.

The method 100 increments the value of the index i, in a step 114, and if the value thereof is less than 2N + 1 (situation symbolized by the test 115 and the link 115-y in FIG. new iteration of the steps 112, 113, 120 and 114, makes it possible to create a second cell in the current row of the table, said cell being associated with a second future fragment Fi, j of the image I. When the 2Nd cell of the line current has been created (situation symbolized by the test 115 and the link 115-n in Figure 2), the line closing tag </ tr> is written in step 115 in the SCP script. The index j is incremented by one unit in a subsequent step 116.

If the new value of said index j is less than 2N + 1 (situation symbolized by the test 117 and the link 117-y in FIG. 2), new iterations of the steps 112, 113, 120, 114, 115 are triggered by the processing 110 method 100, to write the appropriate tags in the SCP script to build a second row of table, and so on, until the value of the index j reaches the value 2N + 1 (situation symbolized by the test 117 and the link 117-n in Figure 2), sign that the last cell of said table has been generated. Step 117 inscribes in the SCP script the closing table tag </ table>.

The SCP script thus developed and associated with the image I, not fragmented, constitutes the signature SG. This can be transferred to the storage means of an LSI signature server according to the invention to be exploited. Such a transmission results from an encoding 130 of the image I and the SCP script in the form of an RSS message requiring the registration of said signature with a remote LSI signature server, for example.

In the end, as indicated by way of example in FIG. 2A, an SCP script is generated.

FIG. 2B describes a second exemplary image I comprising a plurality of clickable zones ZI1 and ZI2 (N = 2), represented by two hatched areas in FIG. 2B. In connection with the example description of a method 100 of FIG. 2, the creation of an array of 2N + 1 = five lines each comprising 2N + 1 = five cells will be programmed in the form of an SCP script. , said cells being provided to respectively trigger the loading and display of twenty-five FI fragments of the image I. The cells are represented by broken lines in FIG. 2B. The image I according to FIG. 2B is identical to that of FIG. 2A. Only a second zone ZI2 was added, zone ZI1 being identical to that of the preceding example.

Thus, the zone ZI1 is therefore characterized by the quadruplet of integers: ZU1 = 42; ZD1 = 114; - ZL1 = 33; - ZR1 = 229; and the zone ZI2 is characterized by the quadruplet of integers: ZU2 = 75; ZD2 = 244; ZL2 = 271; - ZR2 = 365.

We can notice that according to this example that the associated vertical tabulation left corner or right bottom of zone ZI1 (value ZD1) is greater in value than that (ZU2) associated with the top left or right corner of zone ZI2. ZI1 and ZI2 clickable areas will therefore be described as two pairs of adjacent cells, future containers of two pairs of fragments, associated with HREF1 hyperlinker (www.pagel.com), for zone ZI1 and HREF2 (www .page2.com) for zone ZI2.

The SCP script, generated by a method 100, an implementation example of which has been previously described with reference to FIGS. 2 and 2A, applied to a signature SG comprising a clickable image described by FIG. 2B, can advantageously be translated by the instructions in HTML language illustrated by said FIG. 2B.

Let us now study a method of issuing an IF fragment of an image I of a signature SG of an email M, such as the method 200 described by way of nonlimiting example in FIG. 3. Such a method is implemented by the processing unit of an LSI signature server adapted according to the invention.

Such a signature server, such as the LSI server described in FIG. 1, comprises a processing unit and communication means enabling it to interact with one or more third-party electronic devices, for example by receiving requests, in particular requests. in content, emanating from said third party electronic devices, for example implementing a MUA mail client or a MAA signature design agent or client. Said processing unit and said communication means of such an LSI signature server are not shown in FIG. 1 for the sake of simplification. In response to receiving such a content request, content may be developed by the processing unit. In a variant, said processing unit can simply read such content in an MD data memory with which it cooperates. In this case, said content request conveys an identifier of a container or more generally any means for identifying a record hosting said content within said MD data memory. The processing unit encodes said content developed or read in the form of a content message then triggers the transmission of said content message to the requesting electronic device by said communication means of the LSI server.

Such an LSI signature server can thus comprise one or more MD data memories or MP programs or cooperate with some of them distant from said server, to host one or more signatures SG but also to store program instructions P200 whose interpretation or execution by the server processing unit automatically adapts the operation and behavior of said LSI server. The program instructions are generally written in an MP program memory whose access to updating is restricted and limited to an administrator of said server. The signatures and other data inherent to the operation of said LSI server are recorded and updated in one or more MD data stores. Thus, to adapt the operation of an LSI server so that it can operate an email signature SG developed in accordance with the method 100, previously described in connection with FIGS. 2, 2A and 2B, a program memory MP cooperating with the processing unit of the server LSI, comprises instructions of a program P200 whose interpretation or execution by said processing unit of said server LSI causes the implementation of a method 200 of delivery of a fragment of an image of such a signature SG.

As indicated above, in connection with FIG. 1 in particular, an SG signature of an email developed in accordance with the invention mainly consists of the designation of an image I of which at least one ZIn zone is clickable. Associated with said image I, an SCP script, that is to say a series of instructions (for example in HTML) interpretable by a MUA email client, describes a tabular representation of said image I in the form of a set of containers or cells respectively associated with FI image fragments whose geometric data are also explained in said SCP script. Said SCP script also includes possible hyperlinks HREF1, HREF2 associated with certain image fragments in order to make the image I clickable. An SG signature may further include other elements traditionally embedded in email signatures such as one or more blocks of text or one or more other non-clickable images or globally associated with a single hyperlink. Once conceived, for example according to the method 100 described in connection with FIG. 2, such a signature SG (that is to say at least a designated image I associated with an SCP script describing said image I in a form fragmentary container tabular) can be loaded into an MD data store of the LSI server for example by an RSS signature registration request.

The method 200, a preferred embodiment of which is now described with reference to FIG. 3, comprises a first step 201, implemented during the reception, by the communication means of said server, of a content request emanating from a MUA mail client installed on a workstation of a user editor or recipient of an email M with an SG signature whose SGR representation is stored in MD data memory of the LSI server. Such a step 201 consists in identifying the request for content received as an RF fragment request and then extracting from it data transmitted by said fragment request. Such an RF request, as indicated above, can consist essentially of a command in the form of an URL argument of a tag <img> in the form of a string of characters (or query string according to English terminology). . An exemplary method for identifying an RF fragment request implemented by step 201 can advantageously consist in recognizing in said string of characters a predetermined key word, for example the "fragment" keyword as described in connection with the SCP scripts of Figures 2A and 2B.

The method 200 then comprises a step 202 for decoding said extracted data and recognizing, in said string of characters, the name, or more generally a container identifier (for example a file name) associated with the image I designated in said character string, as well as geometric data of a required fragment FI of said image I. Such an image I, as well as a fragment thereof FI are translated into data memory of the LSI signature server by digital representations , respectively RI and RFI in a matrix form of pixels whose integer and respective values describe colors and / or light intensities, which we will name in an undifferentiated manner, in this document for the sake of simplification, "light intensities".

Said geometric data of a fragment FI somehow delimit a view or a subset of the image I, more precisely, said geometric data will be used to develop a new digital representation RFI associated with a fragment of the image from the representation RI of the global image I, as we will study later. Said geometric data can advantageously be extracted from different fields contained in said string of characters and discriminable by the presence of a specific separator (such as the character for example), and constitute a quadruplet of integers U, D, L and R , for which: - U: denotes a first vertical rank rvl of the pixel describing the upper left corner of the fragment FI relative to a reference corner of the image I, preferably the upper left corner thereof; - D: denotes a second vertical row rv2 of the pixel describing the lower left or right corner of the IF fragment with respect to said reference corner of the image I; L: denotes a first horizontal row rhl of the pixel describing the top (or bottom) corner to the left of the fragment FI with respect to said reference corner of the image I; - R: designates a second horizontal row rh2 of the pixel describing the right up (or down) corner of the fragment FI with respect to said reference corner of the image I.

According to the example of a character string associated with an <img> tag of an SCP script described in connection with FIGS. 2A and 2B, the "upper" field of said character string gives the value of U, the field "Lower" gives the value of D, the "right" field gives the value of R and the "left" field gives the value of L. Any other nature or content of geometric data could be used instead or in addition to be exploited . For example, such geometric data could describe a set of characteristic points of a polyline.

The method 200 includes a step 203 for reading, in MD data memory, the digital representation RI of the image I whose container name has also been decoded in step 202. As mentioned above, this advantageously consists of an array of pixels whose integer and respective values reflect the light intensities of said pixels.

The method 200 then consists, in a step 204, in developing a logical view of said representation RI of the image I, to produce a new digital representation RFI of a section or portion, advantageously but not limitatively rectangular, of the structure of image I. For this, as a layer, step 204 consists in keeping in the RFI representation only the pixels identified or captured, for example, by a polyline determined by the geometric data previously determined in step 202 In other words, only the pixels present in the geometric shape constituted by said polyline would be preserved in the RFI representation. Alternatively, and according to the examples studied in connection with FIGS. 2A and 2B, such a step 204 may advantageously create the new digital representation RFI, from a quadruplet of integers R, L, U, D, derived from the data geometrically extracted, in a matrix form of pixels whose integer and respective values are identical to those of the only pixels of the digital representation RI of the entire image I of which: - the horizontal rows are between said first and second horizontal rows L and R, previously described; - The vertical rows are between said first and second vertical rows U and D, also described above.

Such an RFI representation defines an IF fragment of the image I. Such an RFI representation can be stored by the server LSI in a data memory MD so as not to have to produce again such an image fragment IF when a next request for a similar RF fragment. This storage is optional, since the nominal and preferred behavior according to the invention of the LSI server during the implementation of the method 200, consists in elaborating a new fragment FI on receiving any request for an RF fragment.

Steps 205 and 206, aimed respectively at encoding the generated IF fragment in the form of a SF message and triggering the transmission of said SF message to the requesting MUA mail client, are identical to those implemented by a server. signatures or traditional content.

By adapting an LSI signature server according to the invention, a user, such as the user U1, U2 or U3 described in connection with FIG. 1, can respectively edit and receive an email M whose body MC comprises an SG signature produced according to the invention in all transparency.

Indeed, when a MUA mail client interprets the content, usually expressed in HTML, of the body MC of an email M, including the SCP script associated with such an SG signature, the image I, only written in a memory MD data server of the LSI signature server, is dynamically recomposed, like a puzzle, during the display of the email M triggered by the interpretation of the SCP script by the client MUA. Indeed, each cell of the table thus specified in said SCP script has an <img> tag associated with a URL type argument as described above, which automatically triggers the sending of an RF fragment request by the MUA messaging client. to the LSI signature server. It develops, on the fly, said IF fragment according to the geometrical data contained in said SCP script and returns to said MUA client the IF fragment produced. The image I is thus reconstructed by a succession of requests in RF fragments provided by said SCP script. If a fragment is associated with a hyperlink, for example by the presence of a <a> tag containing said hyperlink, the image fragment FI becomes clickable. A user of the MUA messaging client concerned can then click on said image fragment and reach a content whose address is determined by said hyperlink. An SG signature developed according to the invention thus becomes multi-clickable, offering a great flexibility of constitution for its designer, while maintaining a perfect operability.

Claims (12)

A method (200) for delivering a fragment (FI) of an image (I) designated in a signature (SG) of an email (M), said method being implemented by a processing unit of a signature server (LSI) further comprising communication means for receiving a request for content sent by a third-party electronic device (D1, D2, D3) and for sending, in response to such a request for content, a content under the form of a content message, said signature server (LSI) cooperating with a data memory (MD) comprising a container (SGR) associated with said signature (SG), said method (200) being characterized in that the container (SGR) comprises a digital representation (RI) of the image (I) in a matrix form of pixels whose respective integer values describe light intensities and, in that the method (200) comprises: - a step (201) to identify a request for content, received by the means of communication of the signature server (LSI), as a fragment request (RF) and to extract data conveyed by said fragment request (RF); a step (202) for decoding said data extracted from the fragment request and determining: i. the value of the identifier, the container (RSG) of the digital representation (RI) of the image (I); ii. geometric data determining a fragment (FI) of said image (I) by delimiting a subset of said representation (RI) of the image (I); a step (203) for reading, in data memory (MD), the digital representation (RI) of the image (I) whose container identifier value has been extracted; a step (204) for producing a new digital representation (RFI), from the digital representation (RI) of the image (I) and previously extracted geometric data, describing a fragment (FI) of the image ( I); a step (205) for encoding said new digital representation (RFI) describing a fragment (FI) of the image (I) in the form of a content message (SF); a step (206) for triggering the transmission of said content message (SF) to the third electronic device (DI, D2, D3) by the communication means of the signature server (LSI). 2. Method (200) according to the preceding claim, for which data conveyed by a content request consists of a character string and step (201) for identifying such a request as a fragment request (RF) consists of recognize in said character string the presence of a predetermined keyword. 3. Method (200) according to claim 1 or 2, wherein: the geometric data extracted from a fragment request (RF) consist of a set of integers respectively designating characteristic points of a polyline; the step of producing the new digital representation (RFI) describing the required image fragment (FI) consists in creating a digital representation in a matrix form of pixels whose integer and respective values are identical to those of the only pixels of the digital representation (RI) of the image (I) captured by said polyline. 4. Method (200) according to claim 1 or 2, wherein: the geometric data consist of a quadruplet of integers describing: first and second vertical rows in number of pixels, from a reference pixel within the digital representation (RI.) of the image (I), the value of the second vertical row being greater than that of the first; first and second horizontal ranks in number of pixels, from said reference pixel within said digital representation (RI) of the image (I), the value of the second horizontal row being greater than that of the first; the step of producing the new digital representation (RFI) describing the required image fragment (FI) consists in creating a digital representation in a matrix form of pixels whose integer and respective values are identical to those of the only pixels of the digital representation (RI) of the image (I) of which: - the horizontal rows are between said first and second horizontal rows; the vertical rows are between said first and second vertical rows. A computer program product (P20Q) comprising a plurality of program instructions which, when previously loaded into the program memory (MP) of a signature server (LSI), said server (LSI) comprising in addition a processing unit, communication means for interacting with a third electronic device, a data memory (MD), then executed or interpreted by said processing unit of said signature server (LSI), causes the setting implementing a method (200) for delivering a fragment (FI) of an image (I) designated in a signature (SG) of an email (M) according to any one of claims 1 to 4 . 6. A signature server (LSI) comprising a processing unit, communication means for interacting with a third electronic device, a data memory (MD) and a program memory (MP), said server being characterized in that said program memory (MP) stores the instructions of a computer program product (P200) according to the preceding claim. ", Method (100) for generating a signature (SG) of an email (M), said signature (SG) designating an image (I), said method (100) being implemented by a processing unit an electronic device (D4) further comprising a data memory storing a digital representation (RI) of the image (I) in a matrix form of pixels whose respective integer values describe light intensities, an input interface , said method comprising a processing (110) for constructing a representation describing said signature (SG), a step (130) for encoding said structure as a message (RSS) requesting said signature to be registered with a remote signature server (LSI), said method (100) being characterized in that it comprises: a step (102) for collecting N input data sets from the input interface, N being a non-zero integer , for which a set of data of e includes: i. geometric data of a polyline delimiting a clickable area (ZI1, ZI2) and, ii. a string of characters (HREF1, HREF2) translating a hyperlink associated with said zone (ZI1, ZI.2) of the image (I); a step (103) for determining a fragmentation grid from said geometric data of said N sets of input data; and, in that the processing (110) for developing a representation describing said signature (SG) consists of 1 / elaboration of a set (SCP) of program instructions, said program instructions being arranged to: - be automatically interpreted by an electronic mail client (MUA), implemented by a third party electronic device (D1, D2, D3), triggering a graphic rendering of an email (M) including the signature (Se) and, - jointly translating, a association of adjacent containers of fragments (FI), respectively associated with fragment requests (RF), said requests being interpretable by a signature server (LSI) according to claim 6 and each conveying data among which: - the value of 'a login. container (RSG) of the digital representation (RI) of the image (I); geometric data determining a fragment (FI) of said image (I) by delimiting a subset of said representation (RI) of the image (I), said geometric data being determined from the fragmentation grid. 8. Method (100) according to the preceding claim, wherein: the geometric data derived from the input data describe a rectangular polyline; step (103) for determining a fragmentation grid from said geometric data of said N sets of input data is to determine [2N + 1] horizontal tabs (THO, THS) and [2N + 1] vertical tabs (TVO , TV5) with respect to a reference pixel of the representation (RI) of the image (I); the processing (110) for developing a representation describing said signature (SG) as a set of program instructions (SCP) is to produce one or more program instructions for ": i.describing a table of [2N +1] Z containers of image fragments (FI), divided into [2N + 1] lines and [2N + 1] columns, ii) the geometric data conveyed by each fragment request (RF) delimiting the image fragment (FI) being determined according to respectively the horizontal and vertical tabulations previously determined. 9. Method (100) according to the preceding claim, wherein the set (SCP) of program instructions produced to describe the signature (SG) conforms to the programming language "HyperText Markup Language" in English terminology. A computer program product (P100) comprising a plurality of program instructions which, when: - are previously loaded into the program memory of an electronic device (D4), said electronic device (D4) having in in addition to a processing unit, communication means for interacting with a signature server (LSI), a data memory and an input interface, and then executed or interpreted by said processing unit of said electronic device (D4) , causes the implementation of a method (100) for generating a signature (SG) of an email (M) according to any one of claims 7 to 9. An electronic device (D4) comprising a processing unit, communication means for interacting with a remote signature server (LSI), a data memory, an input interface and a program memory, said electronic device (D4) being characterized in that said program memory stores the instructions of a computer program product (P100) according to the preceding claim. An email management system (M) comprising a signature server (LSI) according to claim 6 cooperating with an electronic mail client (MUA) of an electronic device (D1, D2, D3) by means of one or several fragment requests (RF) of an image (I) designated in a signature (SG) of an email (M) displayed by said electronic mail client (MUA). 13. System according to the preceding claim, comprising a second electronic device according to claim 11 cooperating with said signature server by means of a message (RSS) requesting 1 / registration of said signature (SG) with the signature server (LSI). .