FR2960994A1 - System for monitoring and controlling contribution to emission of green house gas from e.g. entity, has agent client associated to sets and/or sub sets of individuals and/or equipments, and identifiers allocated to sets and/or subsets - Google Patents

Abstract

The system has an agent client (CAi) e.g. portable computer (CA1), associated to sets and/or sub sets of individuals and/or equipments, to which identifiers (IDi) are allocated. The sets and sub-sets of identifiers are organized in a tree structure with a root node and a set of parent, son and grandson nodes, to which contribution and sub-contributions to emission of gas from an entity and sub-sets of individuals and/or equipments are associated. Reading-writing access to the sub contributions is realized by reading-writing of structure based on depth of the parent, son and grandson nodes.

Description

The invention relates to a system for monitoring and controlling the contribution to greenhouse gas emissions. At present, the entities and individuals involved in industrial and / or economic activity are confronted with issues of environmental protection and long-term development, known as sustainable development, with maximum respect for the environment. . Such an approach involves a double constraint, that relating to maintaining the sustainability of the activity of the entity and that relating to the minimization of the actual or foreseeable impact of this activity over time on the environment. At the level of any entity, the implementation of such an approach is achieved through the establishment of daily practices and rules having an environmental, social, industrial or economic impact. The methodology to be used to initiate such an approach is then comparable, at the level of the entity and the activity of the latter, to a quality control approach, the general reference of which is external to this entity but whose variables and However, stock parameters are inherent to this business and entity. Such an approach therefore involves the execution of a situation analysis process, the definition of objectives to be achieved, the implementation of actions, the drawing up of balance sheets, the setting up of monitoring and the rules of action. to optimize the objectives and results achieved by or arising from this activity. The implementation of such an approach at the level of each entity is all the more difficult to achieve that it assumes, for the purpose of acceptable efficiency, the adherence of all individuals involved in this activity within the organization. this entity, which implies a priori contradictory constraints, that relating to the establishment of tools allowing easily to implement significant general balances relating to the variables of actions and results of this activity, and that relating to the granularity the intervention process and the finesse of intervention in the control of activity variables. The fineness of ideal intervention corresponds to that of the activity of sets and / or operational subsets of individuals of this entity, or even of each individual, actors of this activity within this entity.

In terms of environmental protection, the objectives, and therefore the essential constraints that are proposed to interested entities, were defined in 2005 by the KYOTO protocol, relating to a schedule for the reduction of carbon dioxide, CO2 emissions, or more generally greenhouse gases, hereinafter referred to as GHGs in the present description. The aforementioned constraints are defined, in order to limit the rise of temperatures to less than 2 ° C compared to the emission levels of the pre-industrial era by reducing emissions: - in 2020: by at least 30% compared to 1990 levels; - in 2050: by at least 50% above 1990 levels. This reduction is the responsibility of the industrialized countries and therefore of any entity of the latter operating. To this end, various organizations have proposed and implemented methods for reducing the dependency of these entities on the consumption of fossil fuels. This is the case in France, in particular, a country in which the French Environment and Energy Management Agency, ADEME, proposed a method of accounting for GHG emissions from the activity of an entity, Designated methods Le Bilan Carbone ®, registered trademark. This method is implemented in the form of numerical spreadsheets that can be executed by a computer and makes it possible to evaluate, in order of magnitude, the GHG emissions generated or induced by the physical processes brought into play by the activity of an entity, necessary processes. the execution of the activity e this entity. In particular, such a method takes into account: - GHG emissions generated directly within the entity; - GHG emissions generated outside this entity, but induced in return for the physical processes brought into play by the latter's activity. Such a method is satisfactory to the extent that the direct and induced GHG emissions are taken into account, which, of course, makes it possible to introduce an almost total indifference of the evaluation method to the actual location of the scale of the planet Earth. Overall, this method makes it possible to define the contribution to the GHG emission of an activity such as the product of activity data representative of physical flows relating to this activity and of emission factors specific to each of these physical flows. For a more detailed description of the aforementioned method, reference may be made to the "Methodological Guide - Version 6.0 - Accounting Objectives and Principles", Bilan Carbone ®, registered trademark, June 2009 published by 'ADEME. The above method has won the support of many entities, industrial enterprises, commercial or relevant organizations.

However, it has the drawbacks below. Implemented mainly in the form of spreadsheets, they can only be manipulated and / or informed by an expert, or even a group of experts, able to convert the variables and parameters of the activity of the entity in terms of physical flows relating to this activity, in relation to the relevant emission factors. Such an operation can therefore only be performed, for a given entity, centrally and by highly qualified personnel, who must be fully aware of the business processes implemented in the context of this activity.

Such a constraint, if it allows the obtaining of significant general assessments, can not in any way allow a real-time intervention at the level of operational sets of individuals, types of work, or even individuals exercising or participating in this activity. This method, because of its eminently centralized character, does not allow the easy real-time involvement of sets of individuals or of each individual actor of this activity in the process of monitoring and controlling the contribution to the broadcast. of GHGs as a whole, nor ultimately the actual involvement in the entity's future. The present invention relates to the implementation of a system for monitoring and controlling the contribution to the GHG emission of an entity making it possible to remedy the aforementioned drawbacks. In particular, an object of the present invention is the implementation of a system for monitoring and controlling the contribution to the emission of GHGs from an interactive and self-adaptive type entity to this entity, to its type. of activity, size and geographic spread across the planet. Another object of the present invention is the implementation of the aforementioned system for performing an audit of the contribution to the emission of GHG sets and subsets of individuals and / or equipment exercising an activity, designated upstream audit, the notion of set and / or subsets of individuals and / or equipment covering that of the unary set, comprising only an individual and / or equipment, for the purpose of introduce maximum granularity in the monitoring and control of this GHG contribution for this entity. Another object of the present invention is furthermore, because of the remarkable nature of the maximum granularity of monitoring and control mentioned above, the implementation of a system for monitoring and controlling the contribution to the emission of GHGs from collaborative type, in which each subset of individuals and / or individuals involved in this activity is fully involved and empowered in any GHG monitoring and control campaign. Another object of the present invention is finally, given the maximum granularity and the collaborative nature of the aforementioned surveillance and control, the implementation of a real incentive and emulation of each individual actors of this activity by the introduction a real individuation of the act of monitoring and controlling the emission of GHGs in real time. The system for monitoring and controlling the contribution to the emission of greenhouse gases generated or induced by the physical processes brought into play by an entity that is the subject of the invention applies to any entity formed by a set individuals and / or equipment associated with them performing a specific activity. It is remarkable that this system includes at least, in the context of a client-server architecture, a dedicated server including at least one calculation tool, in order of magnitude, of the contribution to the emission of gas effect of greenhouse gases, defined as the product of activity data, quantified in physical flows attributable to this activity, and emission factors specific to the aforementioned physical flows, and a directory of sets and / or subsets of individuals and / or equipment carrying out this activity. Each set and / or subset of individuals and / or equipment is allocated a unique coded identifier that makes it possible to segment the contribution to the emission of greenhouse gases by subsets of individuals and / or associated equipment because of the existence of this activity. The system which is the subject of the invention comprises at least one client agent physically associated with each set and / or subsets of individuals and where equipment. This client agent allows the interconnection of each subset of individuals and / or equipment to the dedicated server and the real-time update by transmission of activity data and emission factors messages to the dedicated server. by segmentation, by means of the unique coded identifier of each set and / or subset of individuals and / or equipment associated with them, and contributions to the greenhouse gas emissions attributed to them.

According to another remarkable aspect of the system which is the subject of the invention, the dedicated server comprises memory resources in relative addressing, with respect to the unique identifier, successive temporal contributions to the emission of GHGs of each set and and / or subsets of individuals and / or equipment in successive fixed time slots.

According to another particularly remarkable aspect of the system object of the invention, each unique coded identifier is coded according to a hierarchical coding. The set and the subsets of the unique identifiers coded being organized according to a tree structure. This structure comprises a root node, which is associated with the contribution of the GHG emissions of the entity, and a plurality of successive nodes father, son, grandson, which are associated with the sub-contributions to the emission of gas effect greenhouse of each set respectively subset of individuals and / or associated equipment constituting this entity. The read-write access to the sub-contributions to the emission of GHGs is carried out by reading-writing paths of the tree structure, and thus segmentation, as a function of the depth of the successive father, son and grandson nodes. Other particular noteworthy aspects of the system for monitoring and controlling the contribution to the emission of GHGs that are the subject of the invention will be described in more detail below in the description in conjunction with the drawings in which: FIG. 1a represents, by way of illustration, the general architecture of the system that is the subject of the invention in a client-server configuration; FIG. 1 b represents, by way of illustration, an example of non-limiting implementation of memory resources in relative addressing and of a conditional access module read-write to these storage resources integrated into a dedicated server included. in the architecture of the system which is the subject of the invention represented in FIG. FIG. 2a illustrates by way of example a representation of the tree structure of the set and the subsets of unique identifiers coded according to a hierarchical coding allowing, preferentially, read / write access to the contributions or under contributions to GHG emissions; FIG. 2b represents, by way of nonlimiting example, the implementation, in the dedicated server, of a look-up table allowing selection of the transmission factors as a function of the geographical position of the client agent; FIG. 3a represents, by way of nonlimiting preferential example, an example of implementation of a client agent; FIG. 3b represents, by way of nonlimiting example, the structure of messages exchanged between the client agent and the dedicated server; FIG. 3c represents, by way of non-limiting example, a message exchange protocol of FIG. 3b allowing the execution of the monitoring of the control of the contribution to the emission of GHGs for a set or a sub-unit. set of individuals involved in an activity; FIGS. 4a and 4b illustrate a first and a second screen page displayed on the graphical interface of the client agent for updating the activity data of the set or subset of individuals; FIG. 4c represents, by way of illustration, a third screen page displayed on the graphical display interface of the client agent making it possible to provide interactive assistance with the filling of forms by any individual actor of the activity of the client. entity; FIG. 4d represents, by way of illustration, a screen page allowing the display and / or editing, on the graphical interface of the client agent, of contribution data and contribution projections to the emission of GHGs, as well as as a behavioral recommendation addressed to an individual or a set of individuals involved in the activity of the entity; FIG. 5a represents an architecture of the system that is the subject of the invention, comprising a master dedicated server and at least one slave dedicated server, more particularly adapted to a mufti-sites entity comprising a central site of the main establishment and remote sites of secondary establishments or subsidiaries; - Figure 5b shows the tree structure of Figure 2a specially adapted to the architecture of the system object of the invention illustrated in Figure 5a. The system for monitoring and controlling the contribution to the emission of GHGs generated or induced by physical processes brought into play by an entity formed by a set of individuals and / or equipment associated with them performing a certain activity , in accordance with the subject of the invention, will now be described in connection with Figure 1a and the following figures. As represented in the above-mentioned figure, the system comprises a dedicated server, S, this server including at least one calculation tool, CM, in order of magnitude, of the contribution to the emission of greenhouse gases defined as the produced activity data, quantified in physical flows attributable to this activity, and emission factors specific to physical flows. It is understood, in particular, that the above-mentioned calculation tool can be constituted by an application executable by the central computing unit pP of the dedicated server S, this application being able to advantageously correspond and satisfy the specifications established in France by ADEME and previously mentioned in the description. The dedicated server S further comprises a directory, ANN, sets and / or subsets of individuals and / or equipment exercising the activity of the entity. In FIG. 1 each individual or set or subset of individuals and / or equipment is denoted by Ii (Eqi), where IDi denotes the coded unique identifier of the set, subset of individuals and / or of equipment considered. The ANN directory can be constituted, as represented on the figurel a, by a plurality of computer lists whose elements for each individual, together or subset of individuals and or equipment, include the unique identifier IDi and a sequence of ADi administration data attributed to the individual, the set or subset of individuals and / or equipment Ii (Eqi) considered. As will be observed further in Figure 1a, the system of the invention also includes one or more client agents physically associated with each set and / or subset of individuals and / or equipment . In the aforementioned figure, the client agents are represented indifferently and in a nonlimiting manner by a laptop CA1 (ID1), which is associated with the unique identifier ID1, a mobile terminal type mobile phone CAi (IDi), unique identifier IDi, or a fixed desktop computer, rated CAN (IDN). The aforementioned client agents are connected or likely to be connected to the dedicated server S by a WAN type network, the INTERNET network or any other type of network. Thus, each client agent allows the interconnection of each subset of individuals and / or equipment to the dedicated server S and the updating, in real time, by transmission of messages MADi activity data and factors d relevant emission from the dedicated server S. In particular, the real-time updating of the activity data and transmission factors of the messages makes it possible to perform segmentation by means of the unique coded identifier each set and / or subset of individuals and / or equipment associated therewith editing or displaying activity data attributable to each set and / or subset of individuals and / or equipment associated with these. The concept of real time must be understood, in a campaign of monitoring and control of the contribution to the emission of greenhouse gases, as irreducible to the minimum time slice response time of the exchange of messages MADi, time , day, week, month, quarter or semester of activity data update. A more detailed description of the dedicated server S will now be given in connection with the figurel b.

With reference to the above-mentioned figure, it is indicated that the latter comprises memory resources in relative addressing, vis-à-vis the unique identifier IDi, successive temporal contributions to the emission of greenhouse gases from each set. and / or subset of individuals and / or equipment, in successive fixed time slots. These resources consist of a memory noted P-MEM, which is associated with a conditional access module read-write to the latter in relative addressing, the conditional access module being noted CA on the figure b. By way of nonlimiting example, following the receipt of a message MADi and processing thereof by the central processing unit pP of the server S, the unique coded identifier IDi and the activity data ADi are extracted and transmitted to the CA conditional access module. The conversion of the unique identifier IDi into a physical address APi is carried out either from a look-up table or from a one-to-one address translation function and the activity data ADi are stored in order to update, by order of magnitude, the contribution to the emission of greenhouse gases E-GESi in successive time slots E-GESik for the individual or the group or set or subset of individuals Ii. The index k denotes a time slice index, as will be described later in the description. A preferred non-limiting embodiment of the coding of each unique identifier encoded IDi is now described in connection with FIG. 2a. In general, it is indicated that each unique coded identifier is coded according to a hierarchical coding. Thus, the set and the subsets of the coded unique identifiers are organized according to a tree structure as represented in the aforementioned figure. This structure comprises a root node bearing the reference S and corresponding to the dedicated server, to which may be associated an arbitrary unique identifier, identifying 0 for example. The aforementioned root node is associated with the contribution to the emission of greenhouse gases from the total entity, denoted E-GESO.The tree structure furthermore comprises a plurality of successive father, son and grandchild nodes, to which associated sub-contributions to the emission of greenhouse gases from each set respectively subset of individuals and / or associated equipment constituting this entity. The sub-contributions are noted for each successive father and son node E-GESi, i actually designating the value of the identifier assigned according to the following rule: each child node is assigned an alphanumeric reference 1, 2, 3, etc. concatenated to the alphanumeric reference assigned to the parent node upstream of the latter. There is thus a unique coded identifier, for example the unique coded identifier IDi = 112 for the set or subsets of individuals 1112, and so on, as shown in the drawing of Figure 2a. Read - write access to E - GESi greenhouse gas sub - contributions and E - GESik temporal sub - contributions of the set or subsets of individuals Ii of unique coded identifier IDi is then performed by reading-writing the tree structure, as a function of the depth of the father nodes, son, successive grandsons, by simple addressing on the unique coded identifier and path of the aforementioned tree structure. By such a procedure, the extraction of views concerning the contribution of the emission of greenhouse gases for nodes of the same depth and thus sets of individuals of the same level of responsibility in the entity can be carried out by simple search for the corresponding data, stored by means of unique identifiers coded with the same depth. Because of the highly delocalised and geographically variable nature of the functions performed within an entity by a set of individuals or an individual, especially during business trips for example, the dedicated server S may advantageously be equipped with an LT table of specific emission factors. As represented in FIG. 2b, the specific emission factors consultation table is readable according to the local geographical position, denoted GPSi, of the set and / or the subset of individuals and / or associated equipment and the CAi client agent allocated to them. Thus, the communication of the geographic position of this client agent makes it possible, from the look-up table LT represented in FIG. 2b, to determine the emission factor EFi relevant for the activity conducted during a trip to the foreign. A specific client agent more particularly adapted to the implementation of the system which is the subject of the invention is now described with reference to FIG. 3a.

This client agent CAi, with which the unique coded identifier Ii is associated, is represented in a nonlimiting manner in the form of a mobile phone comprising a graphic interface DIS for displaying messages and / or screens and forms, as well as a keyboard, K, conventionally. The aforementioned client agent may comprise, as shown in FIG. 3a, an I / O input / output interface, a microprocessor pP, supplemented as the case may be by a pPS security microprocessor, and an execution module AP, on the dedicated server S, at least one interactive application for authenticating the set and / or subsets of individuals and / or associated equipment and updating the activity data of the together and / or of the subset of individuals and / or equipment, for temporal slices of activity determined. Preferably, the authentication of the set and / or the subset of individuals and / or equipment Ii (Egi) is performed via the pPS security microprocessor and the data update application. is executed by the microprocessor pP. Finally, in the case where the client agent is implemented on a mobile terminal having network access resources, as shown in FIG. 3a, the latter is advantageously equipped with a local satellite positioning module, noted GPS. It will thus be understood that the transmission of the local position of the client agent CAi to the dedicated server S comprising the look-up table LT allows the selection of the relevant transmission factors EFi. An example of the message structure and the exchange of these between the dedicated server S and each client agent CAi will now be given in connection with Figure 3b and Figure 3c.

In general, the exchanged messages may comprise Req request messages, Ack acknowledgment messages, ADi activity data messages D and Rep response messages. Each of the aforementioned messages comprises, for example, a field relating to the unique identifier encoded IDi and a data field proper, comprising either a request identifier or an acknowledgment identifier, or the activity data ADi or the data. answer DRi. Preferably, the aforementioned messages are encrypted through an appropriate encryption process and then decrypted accordingly. The process of encryption-decryption can be for example a private key and public key process making it easier to manage the management of the diversification of the encryption and decryption keys. The exchange of the aforementioned messages can be executed as shown in FIG. 3c, during a monitoring campaign and in particular by updating the activity data initiated by the dedicated server S. The server S transmits, for example, a message Req request has a CAi client agent for a given set or subset of individuals, or if applicable for all individuals of the entity considered. On receipt of the message, the client agent concerned performs decryption, authentication and processing of the message under consideration. It first transmits an acknowledgment message Ack to the dedicated server S. The latter performs similar operations of decryption, authentication and processing. On successful authentication of the message under consideration, by checking the value of the received unique coded identifier for example, the server S transmits a data message to the client agent CAi considered, and, following an acknowledgment message the aforementioned client agent sends a response message Rep to the dedicated server S. The latter, after decryption, authentication and processing, stores / updates the activity data E-GESi. Various functionalities of the system that are the subject of the invention implemented at the level of the dedicated server S respectively at the level of each client agent CAi will now be described in relation to FIGS. 4a to 4d. Generally, it is indicated that the dedicated server S advantageously comprises an action rule learning engine of the one or more individuals members of the entity in an environment, in particular their business environment. This learning engine is managed by a campaign manager module monitoring and controlling the contribution to GHG emissions. In particular, the updating of the activity data, the filling of the forms and the establishment of the rules of action in the environment are performed by the display / edition of natural language screen pages at the interface level. DIS graphic of the ACi client agent considered. Preferably, the aforementioned screen pages advantageously comprise a data screen screen relating to the activity in question, represented in FIG. 4a, an example screen page intended to facilitate the task of the individual or the group of individuals constituting the set or the subset of individuals performing this activity, page shown in Figure 4b, and a contextual help page, shown in Figure 4c. Each of these pages can be called by a system of tabs, in a conventional manner. Figure 4a shows the first data screen page transmitted by the server S to a client agent considered. It aims at informing the individual actor of the activity considered on the type of its activity, the use of fuels of organic origin for fixed sources, in the example of the aforementioned figure. This page also includes in the clear the name of the emission factor for the use of bark, sawdust, crushed products, organic fuels, with about 30% humidity. The field relating to the consumption of these fuels must be completed by the individual actor and the unit quantifying this consumption is also chosen by the latter. Finally, a field of uncertainty is also left to the discretion of the user, the individual actor. Figure 4b shows the screen page Example previously mentioned. Of course, this screen page corresponds to that of FIG. 4a in which the set of fields to be completed has been completed with an example, the quantification of the consumption being taken equal to 10 and the consumption unit being the ton. Other units can of course be chosen. Finally, the uncertainty field in percent was set as an example at 5. The help screen shown in Figure 4c contains real-life help recommendations. In particular, we can note the consideration of fuels encouraging inventory of the different fuels used by stationary sources for heating, for the production lines and for the fixed machines used, machines with thermal engine. The contextual help clarifies and attracts the attention of the individual actor, in order to avoid the latter taking into account fuels intended for vehicles for which it is not a question of fixed sources for example. Finally, the contextual help indicates the procedure for filling out the form in Figure 4a, specifying, for each type of fuel, an incentive to choose the factor corresponding to the energy used, to make the total calculation consumed in the year. year being here the monitoring time slot given by way of non-limiting example, the calculation being to be reported in the heading quantity consumption, then to indicate, of course, the correct unit of measurement for the fuel or effluent considered. The aforementioned aid finally includes a signal of the existence of several subtotals with an incentive to enter each of these in a specific source having the title of the energy used, each consumption of the same fuel being able to Subtotal object with different units, such as kWh, tons, liters or others. A last signaling invites the individual actor not to enter twice the same consumption with two different units. Other types of screen pages can of course be displayed on the GUI DIS of the client agent ACi considered. These screen pages may consist of pie charts, histogram or other.

In particular, as shown in FIG. 4d, for the purpose of encouraging and emulating for each individual and / or set or subset of individuals and / or associated equipment involved in this activity, the rules of action can advantageously include the display and / or editing, on the graphical interface, of at least one contribution to the emission of greenhouse gases on a plurality of past time slots, for an individual and / or a set or subset of individuals and / or associated equipment operating in that entity or in another entity a comparable activity. In the aforementioned figure, the diagram comprises an ordinate graduated in order of magnitude 0G of maximum value 100 and an abscissa axis graduated in time, that is to say in index k, each value of the index k representing a duration a month. As a non-restrictive example, for a current current month corresponding to month 5, the diagram for earlier time bands 1 to 5 represents the effective contribution to the greenhouse gas emission E-GESik, designated Current for the the individual or the set or subset of individuals Ii (Eqi) equipped with the client agent ACi and having, by way of non-limiting example, a present average value with MVia represented in dashed line. In addition, as also shown in FIG. 4d, the action rules can also include the display and / or edition of a projection of contribution to the emission of greenhouse gases. over a plurality of future time slots, designated Future, for the individual Ii and / or the set or subset of individuals considered, this projection corresponding to estimated values represented in dashed line after the month 5 up to at the end of the monitoring campaign in month 12. A behavioral recommendation regarding the use of physical flows attributable to the activity of the individual and / or the whole or subset of individuals considered may then be introduced. In FIG. 4d, this behavioral recommendation is represented symbolically by a future average value to be achieved, noted MVif, which for incentive purposes is represented less than the current average value MVia previously mentioned. It will further be understood, by way of nonlimiting example, that both the current average value line and the Future average value line can be implemented in the form of an HTML link on which, following a pointer click, the individual actor can trigger the opening of contextual help relative to his current respectively estimated future contribution and to corresponding natural language behavioral recommendations. Finally, the architecture of the system for monitoring and controlling the contribution to the emission of GHGs of the invention is not limited to the existence of a single dedicated server. In particular, the architecture represented in FIG. 5a advantageously corresponds to a system comprising, besides the dedicated server S configured as a master server and assigned to a central site of the main establishment of the entity, one or more secondary servers each assigned to a site remote from a secondary establishment or subsidiary of this entity. FIG. 5a shows a single secondary server, denoted S 'in a nonlimiting manner. The dedicated secondary server S 'operates under the control of the main dedicated server S and makes it possible, by segmenting the contribution to the emission of GHGs by a subset of individuals and / or equipment, to carry out the monitoring and control of this contribution for subsets of individuals and / or equipment assigned to the remote site of the secondary dedicated server S 'considered. With reference to FIG. 5a, it is indicated that the internal architecture of the secondary dedicated server S 'is advantageously similar to that of the main dedicated server S. As regards the allocation of the unique identifiers coded for the set of individuals and / or the set or subset of individuals of an entity whose sites are distributed and configured as shown in Figure 5a, the tree of coded unique identifiers may be substantially retained by the following adaptation: - any server secondary, such as the dedicated secondary server S 'shown in FIG. 5b, is considered as a child node of the dedicated main server S. In these conditions, the coding of the coded unique identifiers can be substantially maintained, with a simple adaptation consisting of for example, to assign the arbitrary identifier 0 to the main dedicated server S and to assign to each dedicated secondary server, such as the server S ', an ad arbitrary character such as a sequence of digits 0, the number of which distinguishes each secondary server.

Other conventions can of course be established, because the concatenation process of alphanumeric characters makes it possible to perform any distinct combination of alphanumeric characters. Finally, each secondary server, and, of course, the dedicated main server S can be assigned network and tree administrator rights, these rights being denoted by A for the main dedicated server S and Aa for the secondary server. dedicated S '. Comparable administrator rights Ab can also be allocated to certain nodes, such as node 11 for all individuals or subsets of individuals 111, having a large number of child nodes and / or small nodes. son, to facilitate the management of the whole. The system for monitoring and controlling the contribution to the emission of greenhouse gases that is the subject of the invention is particularly remarkable because of the high degree of granulometry achieved in the processing of activity data quantifying the contribution to the emission of greenhouse gases generated or induced by the physical processes involved by any entity. It will be understood that any set and / or subset of individuals of the tree of the coded identifiers, as represented in FIG. 2a or in FIG. 5a, can advantageously constitute a unary set, each individual then being able to be directly solicited and reached and ultimately involved in the process of monitoring and controlling the contribution to greenhouse gas emissions of the entity to which it belongs. In addition to this process of inducing and individuation of each individual in the 51st monitoring process, the system object of the invention is furthermore remarkable in that it constitutes, because of this maximum granularity, a collaborative system in which each The individual involved is likely to contribute to the real-time monitoring process.

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