EP0621565A1 - System for centralising heterogeneous information connected to an identity, collected and time-stamped at remote posts - Google Patents

Abstract

The centralising system consists of a plurality of autonomous interactive posts (101..., 201, 301, ...), intended to be used by means of an identification support and connected in a network to a central computer (4); each post includes memory means for storing, with each use of the post, an elementary group of data consisting of at least the identity registered in the identification support, the date and time of use of the post. According to the invention, the memory means of each post are read-accessible and possibly write-accessible by the central computer (4); the central computer (4) knows the structure of the memory means and the format of an elementary data group for each type of application, as well as the address and the type of application of each of the posts to which it is connected, and is able to address the memory means of a post which has been selected in such a way as to retrieve, in the memory means, all the elementary data groups which have been stored since the last enquiry. The system of the invention allows the centralising at the level of a single central computer of information identified and time-stamped from posts dedicated to varied applications, such as access control, the clocking-on of staff..., for analysis and management purposes. <IMAGE>

Description

The present invention relates to a system for centralizing heterogeneous information linked to an identity, collected and time-stamped from delocalized terminals. It particularly finds its application in the collection of all the information which concerns the personnel of a company, and which is acquired and time stamped by means of interactive terminals disseminated in the company, intended to be used by an individual by means of '' an identification support, and dedicated to various applications such as access control, staff pointing, workshop time management, photocopiers, beverage dispensers ...

There are already known, in particular in the field of access control, delocalized terminals which are used by individuals in a company, using an identification medium, such as a magnetic card. For example, document FR.2.635.895 describes an access management system consisting of access control terminals which are used by means of a smart card and which are networked with means of remote management. In this access management system, the function of each access control terminal is only to control access control means as a function of data stored on the smart card and predetermined operating parameters stored in a memory from the access management unit for each terminal. The function of the remote management means is to allow remote configuration of each access control terminal. No data is acquired by the access control terminals to be then centralized and processed by the access management means. The access management system described in document FR.2.635.895 does not allow the centralized collection and processing of information which would be acquired by the remote access control terminals.

However, it is also known to use such terminals dedicated to access control to acquire an identity which is written on the identification medium, as well as the date and time of passage of the individual. There are also other fields, in which interactive terminals are used, which are dedicated to an application, and which allow the acquisition of time-stamped information, and linked to an identity. It can, for example, be terminals dedicated to staff pointing, to the management of beverage dispensers, or to fuel pumps ... The information which is collected by such terminals, in addition to the identity written on the support 'identification, and the date and time of use of the terminal, depend on the application to which the interactive terminal is dedicated.

Currently, it is known, in particular from document EP.391678, to connect a network computer to a central computer, only interactive terminals which are dedicated to the same application, and which thereby enable each use of a terminal , the acquisition and centralization of homogeneous information, that is to say of a group of data always representing the same information and the number of data of which is always identical for each interactive terminal connected to the same network.

In document EP.391678, the centralized collection and processing system of homogeneous information by means of delocalized interactive terminals has a hierarchical structure at three levels. The lowest level consists of a unit called SDRU; the intermediate level is made up of a unit called MDRU, which allows the collection of data acquired by several SDRU units; the highest level consists of a concentrator, managing several MDRU units. This data collection and processing system is applied to the collection of information from remote workstations in a company, so as to calculate in real time the salary of each operator on a given workstation. To this end, an SDRU is associated with each workstation. When an MDRU unit wants to recover data acquired by an SDRU unit, it sends the microprocessor of the SDRU unit a interruption, and the microprocessor of the SDRU unit is responsible for transmitting the acquired data to it. Each SDRU unit therefore does not have any storage means, of the RAM type, directly accessible in read and write mode by an MDRU unit. The same is true between a concentrator and each MDRU unit. In addition, all SDRUs are identical to each other, as are MDRUs and hubs; the information which is acquired by each SDRU, and which goes back up in the hierarchical structure is not heterogeneous.

Currently, it is therefore necessary to have in the company, for each field of application, a centralization system of homogeneous information consisting of identical interactive terminals dedicated to the same application, and connected in network to a central computer.

The aim set by the applicant is to propose a system for the centralization of information collected from delocalized terminals, which overcomes the drawback noted, in particular in document EP.391678, in that it consists of '' a single central computer connected to a plurality of interactive terminals, which can be dedicated to totally different fields of application, and which thereby collect heterogeneous information whose nature and format vary from terminal to terminal other. It is thus possible at the level of this single central computer, to exploit all the time-stamped information which can circulate in the companies and which are linked to an identity, in order to exploit them in terms of analysis and management, in particular accounting.

In known manner, this system consists of a plurality of autonomous interactive terminals, intended to be used by means of an identification medium and connected in network to a central computer; each terminal comprises storage means and processing means, which on the one hand manage, depending on the application to which the terminal is dedicated, one or more peripherals, including at least means for reading the identification medium , and which on the other hand are suitable for each use of the terminal, to be stored in the storage means, an elementary group of data consisting at least of the identity entered on the identification medium, the date and time of use of the terminal.

Typically according to the invention, the storage means of each terminal are accessible in reading and possibly in writing by the central computer; for each terminal, the structure of the storage means and the format of the elementary groups of data depends only on the application to which the terminal is dedicated; the central computer knows the structure of the storage means and the format of an elementary group of data for each type of application, as well as the address and the type of application of each of the terminals to which it is connected, and is suitable to address the storage means of a terminal which has been selected so as to recover, in the storage means of said terminal, all the elementary groups of data which have been stored since the last interrogation of the terminal.

When, at the level of the central computer, it is desired for example to recover all the elementary groups of data which have been stored at the level of all the terminals dedicated to the same application, it suffices to specify to the central computer the type of terminal which wishes to query, i.e. the area of application in question. The latter deduces therefrom all the addresses of the terminals which it must interrogate, as well as the structure of the storage means of these terminals, and the format of each elementary group of data which it must recover. Then he successively reads the storage means of each of the terminals of which he knows the address and the structure, so as to recover all the information which has been stored in these terminals since the last interrogation.

More particularly, the storage means of each terminal of the system of the invention contain a counter variable which is incremented by the processing means each time the terminal is used, which is read by the central computer, before each group recovery operation elementary data stored in the terminal, and which is reset to zero by the central computer once said operation is completed. This variable allows the central computer to know the number of elementary groups that it must recover for a given terminal.

Advantageously, this counter variable is used by the processing means for calculating the addresses for writing the data of each elementary group, in the means for storing the terminal. When all the elementary groups of data stored in the storage means of a terminal have been read by the central computer, the counter variable is zero. In this case, the processing means store the data of the elementary groups again, from the initial address of the zone which is reserved for the storage of the elementary groups of data.

Advantageously, for at least one of the terminals of the system, the management of the peripherals by the processing means depends on the parameters which are stored in the storage means. In this case, the central computer is able to modify the value of these parameters. The central computer can thus configure such a terminal by downloading specific parameters to it.

In a first particular embodiment, being a terminal which can be configured by the central computer, and possibly comprising manual entry means, the processing means are able to authorize or refuse the use of the terminal, after comparing all or part of the information entered on the identification medium and / or possibly all or part of the data entered, with one or more specific parameters, called authorization parameters. In addition to identity, the professional category of the individual can be entered on the identification medium. In this case, the authorization parameters can be for example a list of identities or professional categories which are authorized or not to use the terminal. Another particular authorization parameter may consist of a secret terminal code. In this case, said code is compared with a code entered by the individual using the terminal using manual input means, such as a keyboard.

In a second particular embodiment, the expiration date is written on the identification medium. In this case, the processing means of at least one terminal are capable of authorizing or refusing the use of the terminal after comparing said expiration date with the date of use of the terminal.

In a third particular embodiment, a secret code is written on the identification medium. In this case, for at least one of the terminals comprising manual entry means, the processing means are capable of refusing or authorizing the use of the terminal, after having compared said secret code with the code entered using the means of manual entry.

As this is a terminal dedicated to access control, it preferably combines all the characteristics of the three particular embodiments mentioned above. In this case, the storage means of such a terminal contain at least one parameter called the restriction level, which fixes the ability of the processing means to authorize or refuse the use of the terminal.

Preferably, the means for memorizing the terminals dedicated to access control contain several restriction level parameters, each of these parameters being associated with a time slot and possibly with a day of the week. In this case, the processing means are able to temper the restriction level parameter corresponding to the time slot and possibly the date of use of the terminal.

• La figure 1 représente schématiquement un système particulier constitué par une pluralité de bornes dédiées à des applications différentes et connectées en réseau à un calculateur central,
• La figure 2 est une représentation schématique de l'architecture générale de chacune des bornes du système de la figure 1,
• Les figures 3A, 3B et 3C représentent la structure des moyens de mémorisation respectivement des bornes dédiées au contrôle d'accès, au pointage, et à la gestion de temps atelier,
• Les figures 4A et 4B sont des organigrammes illustrant le fonctionnement des bornes dédiées au contrôle d'accès,
• Et la figure 5 est un organigramme montrant les principales étapes qui sont mises en oeuvre au niveau du calculateur central pour la récupération des informations qui sont stockées dans toutes les bornes dédiées à une même application.

Other characteristics and advantages of the invention will emerge from the following description of a particular embodiment of a centralization system of the invention given by way of nonlimiting example, and with reference to the appended drawings in which:

• FIG. 1 schematically represents a particular system constituted by a plurality of terminals dedicated to different applications and connected in network to a central computer,
• FIG. 2 is a schematic representation of the general architecture of each of the terminals of the system of FIG. 1,
• FIGS. 3A, 3B and 3C represent the structure of the storage means respectively of the terminals dedicated to access control, pointing, and workshop time management,
• FIGS. 4A and 4B are flow diagrams illustrating the operation of the terminals dedicated to access control,
• And FIG. 5 is a flowchart showing the main steps which are implemented at the level of the central computer for recovering the information which is stored in all the terminals dedicated to the same application.

The heterogeneous information centralization system of FIG. 1 consists of three networks 1, 2 and 3 of interactive terminals, which are connected to a central computer 4. Network 1 consists of a plurality of interactive terminals referenced 101, 102, 103, 104, 105, ... which are connected to the same communication bus 100, which bus is connected to the central computer 4 via a communication port of the computer. Similarly, networks 2 and 3 are respectively constituted by interactive terminals referenced respectively 201, 202, 203, 204, 205, ... and 301, 302, 303, 304, 305, ... and connected respectively to communication bus 200 and 300.

The interactive terminals of the system in Figure 1 are distributed throughout the company, and are dedicated to a wide variety of applications. Terminal 101 is for example dedicated to access control, terminal 102 for staff pointing management, terminal 103 for workshop time management, terminal 104 for management of a photocopier, ... All of these Interactive kiosks have the common characteristic of being able to be used by an individual by means of an identification medium, such as a magnetic card on which is registered at least one identity number. All the terminals of the system also make it possible to acquire, at each use, a basic group of data, which is constituted by the identity read on the identification medium, the date and time of use, and additional data, the nature and number of which depend solely on the application to which the terminal is dedicated. For example, for a terminal dedicated to pointing, this additional data will be constituted by a code, entered by an individual using a keyboard and indicating either the start or the end of a work period.

The centralization system of the invention allows the recovery by a single central computer 4, of all the heterogeneous information which is acquired by the interactive terminals in the form of elementary groups of data, for purposes of analysis and accounting management by said calculator.

In a specific embodiment, the central computer 4 was a microcomputer, and the communication buses 100, 200 and 300 were buses commonly called daisy chain, and made up of twisted pair pairs. Each network 1, 2 and 3 was of the RS 485 type, and constituted an asynchronous link between the central computer 4 and each interactive terminal. Data was exchanged between the central computer and each interactive terminal using a specific protocol commonly known as Modbus / Jbus. In addition, the microcomputer was connected to a printer 5 and to an encoder 6 allowing the edition of identification media.

All the interactive terminals of the centralization system of the invention comprise an electronic unit 7 whose internal architecture is shown in FIG. 2 and is advantageously identical for all the terminals, whatever the application to which they are dedicated.

• un numéro d'identité
• une catégorie professionnelle
• une date de péremption
• un code secret de carte.

The electronic unit 7 comprises processing means constituted by a microprocessor 8, controlled by a clock 9, and connected via an internal bus 10 to a memory 11, of EEprom type, containing the software resident in the microprocessor. From the information delivered by the clock 9, the microprocessor 8 is able, each time the terminal is used, to calculate the date (day-month) and the schedule (hour-minute) of use. This microprocessor 8 also manages, via an input / output port 12, a set 13 of peripheral devices. In a specific embodiment, the input / output port is composed of a set of specialized electronic cards, each card being easily removable, and dedicated to managing the communication between the microprocessor 8 and a particular type of peripheral. The device assembly 13 of each terminal of the network comprises at least one reader 14, for decoding the information written on the identification medium 15 which is necessary for the use of the terminal. On this identification medium are written:

• an identity number
• a professional category
• an expiration date
• a secret card code.

In the particular embodiment, this identification medium was a magnetic card. It could also be an electronic badge, a bar code card, etc. Depending on the application to which the interactive terminal is dedicated, the set 13 of peripherals may also include display means. 16, a keyboard 19, reading means 20, of the barcode reader type, as well as various sensors 17 or actuators 18, respectively allowing the input of information generated by a machine, or the control of this machine. This can for example be a photocopier, a beverage dispenser, or a machine mounted in line on a production line.

The electronic unit 7 also includes storage means 21 of the random access memory type, accessible for writing and reading by the microprocessor 8 via the internal bus 10. These storage means 21 are also directly accessible for reading and writing, via a communication port 22, RS 485 type. All the electronic boxes 7 of the terminals of the system of FIG. 1 are connected to one of the communication buses 100, 200 or 300, depending on whether the interactive terminal is part of network 1, 2 or 3. The central computer 4 can thus asynchronously come read or write in the storage means 21, which act as a buffer memory between the microprocessor 8 and the central computer. In a particular embodiment, the electronic unit 7 also includes a parallel input / output port 23, allowing in particular to connect the electronic unit 7 to a printer, a communication port 24, of V24 type, in particular allowing emulation of the electronic unit 7 by a videotex terminal, as well as a serial port, of RS 232 type, which makes it possible to communicate the microprocessor 8, according to the application to which the interactive terminal is dedicated with one or more peripherals, other than those of set 13.

The power supply to the electronic unit 16 is provided by an energy box (sector / battery), which is not shown, and which makes it possible to make the interactive terminal autonomous in the event of a power cut, and more particularly to guarantee the operation of the terminal while preserving in particular the integrity of the information which is stored in the storage means 21.

From the above description of the electronic unit 7, it is clear that the interactive terminals of the system, although being dedicated to different applications, differ from each other only by their peripherals, and by the resident software which is stored in the memory 11. This standardization of electronic boxes 7 has the advantage of allowing easy change of the application to which an interactive terminal is dedicated. For this, it suffices to change the terminal peripherals, as well as the specialized cards of the input / output port 12, and to store in memory 11 the software corresponding to the application to which the terminal is to be dedicated.

According to the invention, the storage means 21 allow the exchange of data between the microprocessor 8 and the central computer 4. Their structure depends solely on the application to which the terminal is dedicated.

• le mode de fonctionnement de la borne, (manuel/automatique)
• le code secret de la borne,
• le nombre de plages horaires pour chaque jour de la semaine,
• le nombre de supports d'identification qui ne sont pas autorisés à utiliser la borne,

et une variable compteur, qui est incrémentée par le microprocesseur à chaque utilisation de la borne.FIG. 3A shows a particular example of structure 26, storage means 21 for a terminal which is dedicated to access control. A such a terminal comprises for peripherals, in addition to the means for reading the identification medium, a keyboard for entering data, and a display. The structure 26 is broken down into six memory zones 26 a , 26 b , 26 c , 26 d , 26 e , 26 f , which are contiguous, and whose size is predefined. Zone 26 a contains, at successive addresses, ten parameters which respectively define:

• the operating mode of the terminal, (manual / automatic)
• the secret code of the terminal,
• the number of time slots for each day of the week,
• the number of identification media that are not authorized to use the terminal,

and a counter variable, which is incremented by the microprocessor each time the terminal is used.

The memory zone 26 b comprises for each day of the week, and for each time slot of a given day, a group 27 of three parameters which respectively define the start time of the range, the end time and the level that is associated with the time slot.

The parameter in zone 26 a corresponding to the operating mode can respectively take the values 0, 1, 2, 3, 4, 5, 6. When this parameter is 0, the terminal is configured in automatic mode, which means that its level of restriction depends on the time slot and the day of use of the terminal. When this parameter has the value 1 to 6, the terminal is configured in manual mode, and the restriction level of this terminal is equal to the value of this parameter.

The memory area 26c contains ten authorization parameters which make it possible to define the professional categories which are authorized to use the terminal.

The memory area 26 d contains a red list containing a maximum of two hundred identity numbers, which are not authorized to use a terminal. The number of identity numbers in this list corresponds to the value of tenth parameter of memory area 26 a .

The memory area 26 e is reserved for storing the elementary groups of data which must be acquired by the access control terminal. In the example illustrated in FIG. 3A, the terminal for access control can store up to six hundred elementary groups of data. Each elementary data group of a terminal dedicated to access control consists of an identity number which is read on the identification medium when the terminal is used, a date (day- month) and a timetable (hour-minute) for using the terminal.

The remaining memory area 26 f is an area which is used only by the microprocessor 8. All the data contained in areas 26 a to 26 d , with the exception of the counter variable, are parameters which make it possible to configure the terminal of access control. These parameters are downloaded into the storage means 21 of a terminal dedicated to access control, by the central computer 4. The memory area 26 e is a buffer area between the microprocessor 8 and the central computer, which is write-accessible by the first and read by the second.

• un numéro d'identité,
• une date de péremption,
• une catégorie professionnelle,
• un code secret de carte.

The flow diagram of FIG. 4A illustrates the operation of the microprocessor 8 of a terminal dedicated to access control. As long as the terminal is not used, the microprocessor 28 executes a background task which corresponds to the succession of steps 28 and 29. The step 28 of updating the restriction level of the terminal consists for the microprocessor, according to whether the terminal is configured in manual or automatic mode, either to take the first parameter of the memory zone 26 a as the level of restriction, or to search in the memory zone 26 b for the level of restriction corresponding to the time slot and the day from the moment. Preferably, the microprocessor 8 performs this search only when the time provided by the clock 9 corresponds to a change in time range during the day. If the microprocessor 8 does not find any time slot corresponding to the time and the day, it displays for the user an "out of service" message and refuses the use of the terminal to any person. If the level of restriction that has been set up to date at step 28 is less than or equal to 2, the access control terminal is said to be free entry, which means that the terminal does not control the passage of individuals and does not store any elementary group of data. If the restriction level is strictly greater than 2, the microprocessor performs step 29 by displaying the message "pass card". The microprocessor repeats step 28 and, if necessary, step 29, as long as no individual is present before the access control terminal. When an individual passes his magnetic card 15 through the reading means 14 of the terminal, the microprocessor acquires all the information which is written on this magnetic card, in this case:

• an identity number,
• an expiration date,
• a professional category,
• a secret card code.

Once all this information has been read by the microprocessor 8 (step 30), the latter proceeds to a verification step 31 of the individual's right to use the terminal. This verification step is illustrated by the flow diagram of FIG. 4B, the different steps of which are sufficiently explicit for the person skilled in the art and will therefore not be repeated in the present description.

If after verification, the individual holding the magnetic card is authorized to use the terminal, the microprocessor 8 performs step 32, depending on the peripherals it controls. This may for example involve controlling the timed opening of a door, then closing. If the microprocessor 8 detects an error in the application, for example a bad door opening or a non-crossing of the door, the microprocessor resumes the succession of steps which has just been described from step 29. If the application was carried out correctly, the microprocessor successively performs steps 33 to 38 which correspond to a writing in the memory area 26 e of the storage means 21, of an elementary group of data. Step 33 consists of a reading by the microprocessor of the counter variable, contained in the zone 26 a . This value allows the microprocessor 8 to calculate the address for writing the identity number, in step 34, in the memory area 26 e . The calculation of the writing address of the date step 35 and of the timetable step 36 in the area 26 e is carried out by successively incrementing the writing address of step 34. Once all the data of the elementary group has been saved in the storage means 21, the microprocessor modifies the counter variable the value of the memory area 26a in the incrementing then resumes its background corresponding to steps 28 and 29.

FIGS. 3B and 3C show particular examples of structure 38 and 39 of the storage means 21 respectively of a terminal dedicated to pointing, and of a terminal dedicated to workshop time management. The memory areas 38 a and 38 b of the structures 38 and 39 are reserved for the storage of the counter variable. The memory areas 38 b and 39 b are reserved for storing elementary groups of data. As this is a terminal dedicated to pointing, the elementary group of data differs from the elementary group of a terminal dedicated to access control in that it includes additional data which is a code entered by the individual using the terminal using a keyboard, and indicating whether the individual begins or finishes his work. Being a terminal dedicated to workshop time management, the elementary group of data differs from that of the pointing terminal in that it comprises two additional data which are constituted by the first and second parts of a number of business. The memory areas 38 c and 39 c are reserved only to the microprocessor 8. The score terminals and workshop time management do not realize, unlike dedicated terminals for access control, verification of right of use of the terminal by the individual. These terminals are only satisfied with acquiring, at each use, a basic group of data, in particular by managing a keyboard for entering the start or end code, and if it is a time management terminal workshop, for entering the business number in two parts.

The operating diagram of the microprocessor of the terminals pointing and time management workshop is not explained in this description, but is nevertheless within the reach of the skilled person who can adapt by simplifying the flowchart of Figure 4A, knowing that whatever the application to which the terminal is dedicated, before and after each write of an elementary group of data in the storage means 21, the microprocessor 8, respectively reads the counter variable, in order to be able to calculate the different write addresses, and modifies this variable in the storage means 21, by incrementing it.

The structure of the storage means 21 of a terminal, as well as the format of the elementary groups which are acquired by this terminal at each use, depend solely on the application to which this terminal is dedicated. Those skilled in the art can, without departing from the scope of the invention, define for each application, a particular structure and a particular format of elementary groups of data, different from those represented in FIGS. 3A, 3B and 3C and which have have been given only as non-exhaustive examples.

The invention is also not limited to access control, time attendance or workshop time management applications, but covers all of the company's applications that can be managed by means of a terminal. We can cite as a non-exhaustive example the use of terminals dedicated to machine management, such as a photocopier, drink dispenser, fuel pump ... and which allow on the one hand to control the right d use of the machine by an individual in the company, and on the other hand to count the quantities consumed by the individual.

The software structure of the central computer 4 is organized into three levels. The first level contains the configuration of each network, 1, 2, 3 on which the various terminals of the system are installed, makes it possible to manage a database of company personnel, with a view to editing magnetic cards, and allows all the terminals dedicated to access control to be configured, by downloading the parameters into the storage means 21 of these terminals memory areas 26 a , 26 b , 26 c and 26 d .

The configuration of the network is contained in a file, in which are specified for each terminal of the centralization system of FIG. 1 the address (or number) of the terminal on the network, and the application to which this terminal is dedicated. Regarding the network illustrated in Figure 1, we will find for example in this configuration file, the numbers (or addresses) of terminals 101, 102, 103 and 104, respectively associated with access control, pointing, workshop time management, and photocopier management. The number of these terminals is chosen so that it is characteristic of the network to which the terminal is connected. Thus, from the terminal number, the computer is able to know the network, 1, 2 or 3 to which it is connected.

The second level is broken down into as many separate modules as there are different applications. All these modules however have the same functionalities, among which the interrogation of all the terminals corresponding to the application of the module, with a view to recovering all the elementary groups which have been acquired by said terminals. Each module also knows the structure of the storage means 21 and the format of an elementary group of data which correspond to the application of the module.

The third level also consists of one module per application, offering statistical and management functions (counting, averages, accumulation, ...) from the data that was collected at the second level.

FIG. 5 shows the flow diagram making it possible to illustrate the main functionality of each module of the second level, which is the interrogation of the terminals dedicated to the application of the module. This interrogation is done in the following way. The user of the central computer 4 specifies at the first level the type of application for which he wishes to retrieve the information. Depending on the application, the first level launches the module that corresponds to the application that has been specified by the user. The different steps implemented by this module are illustrated by the flowchart in Figure 5. We start by opening, or creating if necessary, a file which is intended to receive all the elementary groups of data which we are going to recover (step 40). The next step is to retrieve from the level 1 configuration file, the following terminal number, and the application with which it is associated. If this application does not correspond to the application of the module, step 41 is repeated, until possibly finding a terminal number with which the application which has been specified by the user of the central computer 4 is associated. step 41, a terminal number associated with the application of the module is recovered, the central computer 4 performs step 42, which consists in recovering from the storage means 21 the terminal whose number has been found at the step 41, the value of the counter variable which is contained in the storage means 21. If this counter variable is zero, the central computer 4 deduces therefrom that no elementary group of data has been acquired by this terminal since the last interrogation, said terminal therefore not having been used. In this case, we pass to the next terminal number, repeating step 41. If on the other hand the counter variable is not zero, steps 43 to 47 are performed iteratively as many times as the value of this counter variable. Steps 43 to 46 correspond to the recovery in the storage means 21 of the terminal, of an elementary group of data. Step 47 corresponds to a saving in the file which was created or opened in step 40, of the elementary group of data which is recovered, associated with the number (or address) of the terminal which is interrogated. If the counter variable which was recovered in step 43 is equal to three, there are three elementary groups of data to be recovered in the storage means 21; steps 43 to 47 are therefore carried out three times.

Once all the elementary groups of data have been recovered by the central computer 4, the latter resets the counter variable to zero in the storage means 21 of the terminal. The number of data which are recovered in step 47 depends on the format of the elementary groups which are acquired by the terminal and therefore on the application to which the thick headed. The read or write addresses in the storage means 21 of the terminal which are calculated in particular in steps 42, 43, 44, 45, 46 and 48 depend on the structure of these storage means which is known by the module corresponding to the application queried.

Step 41 is carried out for all the terminals of the centralization system of the invention. When there is no more terminal number to read in the configuration file, the file from step 40 is closed (step 49). The interrogation requested by the user is finished. The file which was closed in step 49 contains all the elementary groups of data which have been recovered, associated with a terminal number.

• d'optimiser le contrôle des frais généraux
• de connaître les coût de production
• de gérer un restaurant d'entreprise
• de connaître les charges de fonctionnement d'un parc automobile
• d'accélérer des tâches routinières (facturation, imputation analytique ...)
• d'assurer la sécurité des bâtiments de l'entreprise
• d'automatiser le pointage ( prépaix , horaires libres, ...)
• de contrôler la circulation dans l'entreprise
• de gérer le fonctionnement d'un stock de magasin
• de contrôler les consommations d'un photocopieur ou de tout autre machine, et d'imputer son utilisation
• de gérer des abonnements (distributeur de boissons, ...).

This file can be used at the second level to consolidate a central database, shared by all the modules associated with an application. The information contained in this central database is used at the third level, for analysis and management purposes. Depending on the different applications to which the system's terminals are dedicated, it is thus possible for a company, thanks to the centralization of all the heterogeneous information which is acquired and time-stamped by the terminals, in relation to an identity:

• optimize overhead control
• to know the production costs
• to manage a company restaurant
• to know the operating costs of a fleet
• to speed up routine tasks (invoicing, analytical allocation, etc.)
• ensure the security of company buildings
• to automate the pointing (prepaix, free hours, ...)
• to control the circulation in the company
• manage the operation of a store stock
• to control the consumption of a photocopier or any other machine, and to charge its use
• manage subscriptions (vending machine, ...).

Claims (9)

Centralization system of heterogeneous information linked to an identity, collected and time-stamped from delocalized terminals, of the type consisting of a plurality of autonomous interactive terminals (101, ..., 201, .., 301, ...), intended to be used by means of an identification medium (15) and connected in network to a central computer (4), each terminal comprising storage means (21) and processing means (8, 9, 11) which on the one hand manage, depending on the application to which the terminal is dedicated, one or more peripherals (13), including at least reading means (14) of the identification medium (15), and which on the other hand, are suitable for each use of the terminal, to store in the storage means (21), an elementary group of data consisting at least of the identity written on the identification medium, the date and time of use of the terminal, characterized in that the storage means (21) of each terminal are accessible in reading and possibly in writing by the central computer (4), in that for each terminal, the structure of the storage means (21) and the format of the elementary groups of data are solely a function of the application to which the terminal is dedicated, and in that the central computer (4) knows the structure of the storage means (21) and the format of an elementary group of data for each type of application, as well as the address and the type of application of each of the terminals to which it is connected, and is capable of addressing the storage means (21) of a terminal which has been selected so as to recover, in the storage means (21) of said terminal, all the elementary groups of data which have been stored since the last interrogation of the terminal. System according to claim 1 characterized in that the storage means (21) of each terminal contain a counter variable which is incremented by the processing means (8, 9, 11) each time the terminal is used, which is read by the central computer (4), before each operation of recovering the elementary groups of data stored in the terminal, and which is reset to zero by the central computer (4), once said operation is completed. System according to Claim 2, characterized in that the counter variable is used by the processing means (8, 9, 11) for the calculation of the writing addresses of the data of each elementary group, in the storage means (21). System according to any one of Claims 1 to 3, characterized in that for at least one of the terminals, the management of the peripherals by the processing means depends on parameters which are stored in the storage means (21), and in that the central computer (4) is able to modify the value of these parameters. System according to Claim 4, characterized in that for at least one of the terminals possibly including manual input means, the processing means (8, 9, 11) are capable of authorizing or refusing the use of the terminal, after having compared all or part of the information entered on the identification medium (15) and / or possibly all or part of the data entered, with one or more particular parameters, called authorization parameters. System according to Claim 4, characterized in that an expiration date is written on the identification medium, and in that the processing means of at least one terminal are capable of authorizing or refusing the use of the terminal, after comparing said expiry date with the date of use of the terminal. System according to Claim 4, characterized in that a secret code is written on the identification medium, and in that for at least one of the terminals comprising manual entry means (19), the processing means are capable of authorizing or to refuse the use of the terminal, after comparing said secret code with the code entered using manual input means. System according to claims 5, 6 and 7 characterized in that the storage means (21) of at least one terminal (101) dedicated to access control contain at least one parameter called level of restriction, and in that the ability of the processing means to authorize or refuse the use of the terminal (101) is a function of the value of this parameter. System according to Claim 8, characterized in that the storage means (21) of the terminals (101) dedicated to access control contain several restriction level parameters, each associated with a time slot and possibly with a day of the week, and in that the processing means (8, 9, 11) are capable of recovering the restriction level parameter corresponding to the time slot and possibly to the date of use of the terminal.

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